Anatomically adapted ingestible delivery systems and methods

ABSTRACT

Methods, devices and systems for delivering a device assembly using a shaped body allowing for ease of ingestion of a gastric device into a gastric space, allowing the gastric device to expand to occupy volume within the gastric space and, after an effective period of time release from the body.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a non-provisional application of U.S. Provisional Application No. 61/886,417 filed Oct. 13, 2013 and a non-provisional of U.S. Provisional Application No. 61/722,931 filed Nov. 6, 2012, and is a continuation in-part of U.S. patent application Ser. No. 14/069,776 filed Nov. 1, 2013 which is a continuation-in-part of U.S. patent application Ser. No. 13/773,516 filed Feb. 21, 2013, which is a non-provisional of U.S. Provisional Applications Nos. 61/762,196 filed Feb. 7, 2013; 61/601,384 filed Feb. 21, 2012; 61/645,601 filed May 10, 2012; 61/647,730 filed May 16, 2012; 61/663,433 filed Jun. 22, 2012; 61/663,682 filed Jun. 25, 2012; 61/663,683 filed Jun. 25, 2012; 61/674,126 filed Jul. 20, 2012; and 61/699,942 filed Sep. 12, 2012, the entirety of each of which is incorporated by reference.

BACKGROUND OF THE INVENTION

The present invention generally relates to the field of devices that temporarily occlude spaces within the body to provide a therapeutic effect.

According to 2010 World Health Organization data, 198 million Americans over the age of 15 are above target weight. Of these individuals, 89 million are considered overweight (25<Body Mass Index<30) and 109 million are considered obese (Body Mass Index >30). Worldwide, more than 1.4 billion adults age 20 and over are overweight, and 500 million are obese. Obesity places patients at increased risk of numerous, potentially disabling conditions including type 2 diabetes, heart disease, stroke, gallbladder disease, and musculoskeletal disorders 1,2,3. Compared with healthy weight adults, obese adults are more than three times as likely to have been diagnosed with diabetes or high blood pressure 4. In the United States it is estimated that one in five cancer-related deaths may be attributable to obesity in female non-smokers and one in seven among male non-smokers (>=50 years of age). On average, men and women who were obese at age 40 live 5.8 and 7.1 fewer years, respectively, than their healthy weight peers.

Gastric bypass surgery is the current gold standard treatment for patients with a body mass index (“BMI”) of greater than 40. Gastric bypass surgery is also an option for those with a BMI between 35-39 with obesity-related co-morbidities. While gastric bypass surgery results in decreased food consumption and weight loss for a majority of recipients, it requires life-altering, permanent anatomic modifications to the gastrointestinal tract and can result in severe complications. Gastric bypass and related surgical procedures are also expensive, costing about $22,500 (by laparoscopy). For these reasons, only about 250,000 surgical obesity procedures are performed per year in the US.

For the vast majority of the overweight and obese population for whom surgical obesity procedures are not appropriate, few efficacious and affordable interventions are currently available. Diet and exercise remain the front line approaches to obesity, however this approach has at best slowed the growth of the epidemic. To date, drug therapies have dose limiting side effects or have lacked meaningful long term efficacy.

One less-invasive intervention that has begun to gain popularity is an intragastric balloon. Intragastric balloons can be placed endoscopically or positioned using other methods and generally must be removed endoscopically or rely on the body's natural digestive processes for removal. Many intragastric balloons are placed endoscopically because they are too difficult for the typical patient to swallow.

The present invention also includes devices and systems that generally relate to the ingestion of objects by swallowing and the field of oral delivery of compositions or apparatuses. More particularly, the invention relates to the oral delivery to the stomach of objects, including large volume objects, with greater ease than is achieved with conventional oral dosage forms. The devices can also be delivered to any part of the body, including but not limited to the digestive tract and/or the gastro intestinal system.

Typically, the “size OOO” capsule is the largest volume dosage form administered to adult, human patients. It is cylindrical and symmetrical with rounded ends. The OOO capsule's maximum enclosed payload is about 1.37 ml, its outer diameter is 9.97 mm and its height (“locked length”) is 26.4 mm. Typically, manufacturers of medical devices that must be swallowed have sought to replicate the OOO capsule. For example, the PillCam® SB video capsule from Given Imaging Ltd has an outer diameter of 11 mm and a height of 26 mm.

The human capacity to swallow a particular volume of a given material is a function of a number of factors including that material's shape and consistency (that is, what it feels like to the mouth and throat). A highly deformable material, such as a raw oyster, can be comfortably swallowed in volumes nearing 20 milliliters. On the other hand, rigid objects can typically only be comfortably swallowed (if at all) in substantially lower volumes; in fact a meaningful proportion of human patients report difficulty in swallowing even the smallest pills when in a particularly hard format.

A number of technologies have been described that are intended to render swallowing more facile, particularly for individuals with compromised swallowing abilities. In U.S. Pat. No. 3,418,999, Davis describes a method of swallowing a pill with a density less than 1 floating on a pool of water in the mouth. The floating pill is swallowed with the head in a downwardly bowed position.

Others have proffered mechanical barriers to prevent induction of the gag reflex during attempted swallowing. In U.S. Pat. No. 5,643,204, Cover teaches an intraoral shield over the soft palate held in place by incorporated tooth imprints. The shield is intended to prevent pills in the mouth from contacting gag-reflex-activating tissue.

Others teach softening and/or lubricating the oral dosage form to facilitate swallowing. In U.S. patent application Ser. No. 10/590,282, Soltero teaches incorporation of a gelatinous, hydrated polymeric matrix that facilitates swallowing due to its gelatinous consistency and textural properties. In a similar vein, in U.S. patent application Ser. No. 12/866,715, Craig et al. teach an at least partial surface covering for a traditional capsule comprising a lubricating, edible gel composition to assist swallowing. In U.S. Pat. No. 6,337,083, Fuisz teaches an oral composition comprised of a base liquid and an additive such that a solid object to be swallowed is less likely to become lodged or stuck on tongue, throat, palate or esophageal surfaces of the user. In U.S. Patent RE39125, Fukui et al. teach a swallowing-assistive drink comprised of a viscous liquid or a gelatinoid of a defined viscosity intended to be consumed with medicine.

Other technologies have been described in which the dosage form is modified as to shape. For instance, in U.S. Pat. No. 8,383,135 Fuisz teaches solid dosage forms which are claimed to facilitate rapid and reliable oral, esophageal and GI transit by having a reduced surface area of the contact patch, i.e., the area of contact between the dosage form and the bodily surface (viz., having a smaller contact patch than conventional dosage forms).

These approaches are directed at improving the swallowing success of patients, particularly patients with impaired swallowing function. Further, these approaches are directed to the ingestion of pharmaceutical or neutraceutical compounds. Finally it is noted that many of these approaches are directed to means for adapting pre-existing dosage forms, for example a standard size and shape hard capsule, to be more easily swallowed by, for example, embedding the existing dosage form in a pocket of the described material.

There remains, therefore, a need for an oral dosage form that increases the maximum volume object that can be consistently swallowed with reasonable patient comfort. There also remains a need for an ingestible delivery system that is designed for the delivery of large, non-dissolvable devices, for example, gastric balloons.

The devices, methods, and systems discussed herein are intended to provide an effective treatment for obesity. Moreover, the devices, methods, and systems described herein are not limited to any particular patient population and can even be applied to clinical areas outside of obesity. The dosage form described herein can be applied to facilitate the swallowing of various medical devices other than intragastric balloons or to the swallowing, for example, of large pharmaceutical doses or larger volumes of distasteful liquids.

SUMMARY OF THE INVENTION

The present invention relates to devices and methods for occupying a space within a patient's body. In particular, the devices and methods can be used within a gastric space. However, the devices and methods can be used in any part of the body.

The devices described herein can also be used for delivery of drugs, pharmaceuticals, or other agents where such items can be delivered on a skin of the device, within a reservoir, in a filler of the device, or anywhere on the device. Such agents can be released over time.

The present invention relates generally to an oral dosage form for administration to a human. More particularly the present invention relates to dosage forms, or delivery systems for ingestible payloads, wherein the payload may be an object such as a medical device, a compound such as a pharmaceutical or neutraceutical, or a liquid, wherein further the volume of the payload is greater than the volume comfortably swallowed by typical human adults when presented in conventional dosage forms.

The present invention comprises a deformable, ingestible delivery system, also called an oral dosage form herein, that improves the probability of successful ingestion when compared with a hard dosage form of the same total volume. The present invention further comprises a range of shapes and sizes for the dosage form that conforms to or is adapted to the human anatomy. The term oral dosage form, as used herein, means a shaped object that facilitates swallowing of a payload for delivery to the stomach, digestive tract, and/or distal gastrointestinal system. In some instances, for example, the payload is a pharmaceutical compound while in other examples the payload may be an apparatus or device.

In one aspect the deformable, ingestible delivery system comprises a gastric device having a compliant shaped body. In one aspect the shaped body is a substantially uniform, visco-elastic material.

In another aspect variations of the shaped body are formulated to dissolve in the gastric environment within 1 to 20 minutes.

In another aspect the shaped body is designed to split open or rupture when subjected to an internal pressure or force.

In another aspect the shaped body is shaped to conform to the anatomy of the human mouth, throat and esophagus.

In another aspect the surface of the shaped body comprises one or more outer layers of material encapsulating a layer of compliant material, wherein the layer of compliant material may be substantially uniform or may be an aggregation of discrete particles.

In one aspect, variations of the outer layer are formulated to dissolve in the gastric environment within 1 to 20 minutes.

In another aspect, the deformable, ingestible delivery system's volume ranges from 0.5 ml to 18 ml.

In another aspect, the oral dosage form comprises a Y-axis (e.g., the lingual-palatal axis when the dosage form is placed in the oropharynx) “height” which is smaller than its “width” or “length” (i.e., the X-, or cross-buccal axis and the Z-, or lingual axis, respectively). The oral dosage form's Y-axis “height” ranges from 5-14 mm. The oral dosage form's X-axis “width” ranges from 8-35 mm and the oral dosage form's Z-axis “length” ranges from 8-60 mm.

The above and other features of the invention including various novel details of construction and combinations of parts, and other advantages, will now be more particularly described with reference to the accompanying drawings and pointed out in the claims. It will be understood that the particular method and device embodying the invention are shown by way of illustration and not as a limitation of the invention. The principles and features of this invention may be employed in various and numerous embodiments without departing from the scope of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing and other objects, features and advantages of the methods, devices, and systems described herein will become apparent from the following description in conjunction with the accompanying drawings, in which reference characters refer to the same parts throughout the different views. The drawings are not necessarily to scale; emphasis has instead been placed upon illustrating the principles of the invention. Of the drawings:

FIG. 1A, illustrates an example of a gastric device assembly prior to assuming an active profile.

FIGS. 1B and 1C show partial cutaway views of examples of device assemblies for use in occupying space within a body.

FIG. 1D illustrates the variation of the device shown in FIG. 1A as the device assembly assumes an active profile.

FIG. 1E shows a device assembly after it is inflated, expanded, or otherwise transitioned to achieve a desired active profile.

FIG. 1F illustrates a state of a device assembly after a physician, patient, or other caregiver desires to initiate release the device assembly from the body.

FIG. 2 shows a device assembly or construct in a hydrated or active profile whose outer “skin” defines a material reservoir or pocket.

FIGS. 3A to 3E illustrate additional variations of device assemblies 100 having various active profiles.

FIG. 4 illustrates a variation of a fluid transfer member also having a sealable fluid path for use with the device assemblies described herein.

FIG. 5 shows a variation of a tunnel valve.

FIG. 6A illustrates a partial view of a variation of an invaginated section of a skin of a device assembly.

FIGS. 6B through 6D illustrates a partial view of the interior of a device assembly comprising an invaginated section of the skin further having energy storage element that assists in opening of the device in response to an exogenous trigger.

FIG. 6E provides a schematic illustration of another example of a device assembly having a release material located on a surface of the skin.

FIGS. 7A and 7B show one example of an exploded, assembly view of a device assembly before and after inversion.

FIGS. 7C and 7D illustrate the fabrication of a tapered or conical inverted section.

FIGS. 7E to 7F illustrate variations where the inverted section includes features to increase retention of a release material to a wall of the inverted section.

FIGS. 7G to 7H illustrate variations where the inverted section includes features to improve the sealing of the inverted section.

FIG. 7I, shows a variation of a spring loaded clamp combined with a release material for temporarily securing an inverted section.

FIG. 7J shows another variation in which the inverted section comprises a separate element that is bonded or otherwise affixed to a device body.

FIG. 7K shows a variation where an inverted section comprises an integral part of material forming the device body.

FIGS. 8A and 8B show an additional variation of a portion of a device assembly that provides a control over the fluid permeable path through otherwise impermeable material surface.

FIG. 9A shows another aspect of devices as described herein comprising one or more fluid transport members.

FIG. 9B also illustrate a device having a delivery system attached thereto.

FIGS. 10A and 10B an example of a valve driven by expansion of filler material within a reservoir of the device assembly.

FIGS. 10C and 10D show another variation of a valve.

FIG. 10E shows a hybrid valve wherein each hybrid flow control layer is generally rectangular and the impermeable region and permeable region are triangular.

FIG. 10F shows an exploded view of a valve assembly, a permeable region in one individual flow control layer may be, for example, a circular region, and the impermeable region may be an annulus disposed around the circular permeable region.

FIG. 11A illustrates another variation of a device having a fluid transport member that comprises a fluid wick that extends into a reservoir of the device.

FIG. 11B shows the exterior segment of liquid wick structure immersed in a liquid causing liquid to be drawn into the absorbent wick material of liquid wick structure and further drawn from the wet wick.

FIG. 12A, shows an exemplary embodiments of liquid wick structure fluidly coupled to a secondary, interior bag, pouch, or other container.

FIG. 12B illustrates another embodiment of a device having multiple liquid wick structures.

FIG. 12C, shows an interior segment of a single liquid wick structure that is divided into two or more sub-segments.

FIG. 12D shows a wick structure affixed to a portion of the interior of the reservoir.

FIG. 13A illustrates a variation of a tunnel valve as discussed above that forms a sealable fluid path preventing material from escaping from the interior of the device.

FIG. 13B shows a cross sectional view of tunnel taken along line 13B-13B of FIG. 13A.

FIG. 13C shows the tunnel closing.

FIGS. 13D to 13G show a conduit that is mechanically coupled to a tunnel valve.

FIG. 13H shows a tunnel valve including a swellable substance between layers of the tunnel valve and a conduit.

FIGS. 13I and 13J shows the use of a spring loaded closure device that aids in sealing of a tunnel valve.

FIG. 14 shows a device assembly compressed to fit within an oral dosage form such as a pill, capsule, sleeve, or other form that enhances the ability of positioning the device via ingestion or swallowing without the aid of another medical device.

FIG. 15A shows the swollen mass of various hydrogels after exposure to different solutions.

FIG. 15B depicts the swelling performance of poly(acrylamide-co-acrylic acid) superporous hydrogel in solutions at different pHs.

FIG. 15C depicts the swelling performance of a chitosan/poly(vinyl alcohol) superporous hydrogel in solutions having varying pH levels.

FIG. 16 is a table of standard hard gelatin capsules;

FIG. 17A is a notional diagram of the delivery system;

FIG. 17B is a notional diagram of another variation of the delivery system;

FIG. 17C is a notional diagram of a third variation of the delivery system;

FIG. 18 is a cut-away cartoon view of the human throat;

FIG. 19 is perspective view of an embodiment of the delivery system;

FIG. 20 is a side view of an embodiment of the delivery system;

FIG. 21 is a top view of an embodiment of the delivery system;

FIG. 22A is an end view of an embodiment of the delivery system;

FIG. 22B is an end view of another embodiment of the delivery system and;

FIG. 23 is a qualitative illustration of the relationship between system size, shape, and consistency.

DETAILED DESCRIPTION OF THE INVENTION

The following illustrations are examples of the invention described herein. It is contemplated that combinations of aspects of specific embodiments or combinations of the specific embodiments themselves are within the scope of this disclosure. While the methods, devices, and systems described herein are discussed as being used in the stomach or gastric space, the devices, methods, and systems of the present disclosure can be can be used in other parts of the body where temporary occlusion of a space might be required or beneficial. The present disclosure is related to commonly assigned to US Publication No. 2011/0295299 filed Mar. 2, 2011, the entirety of which is incorporated by reference.

FIG. 1A, illustrates an example of a gastric device assembly 100. In this example, the gastric device assembly or construct 100 can reside in a stomach (typically of a mammal) for an extended period of time. One benefit of such a device is that, when partially or fully deployed, the construct 100 occupies volume within the stomach to produce a therapeutic effect, e.g., to stimulate the sensation of satiety, and resists passage from the body by normal body function. As illustrated below the construct generally comprises three states: a pre-deployment configuration (FIG. 1A); a deployed or active configuration (FIGS. 1D, 1E); and a release configuration (FIG. 1F). As noted above, the device can also be used for therapeutic benefits that do not involve occupying volume (e.g., drug delivery, creation of a cavity by separating adjacent tissue, etc.).

FIG. 1A illustrates a variation of the device 100 after placement within a stomach 2. As described herein, the initial configuration of the device 100 includes a compact state that allows placement within the body. The device can be in a pill-type configuration or any other shape that permits swallowing. Alternatively, the device 100 can be positioned by the use of a scope type device, catheter, or other medical positioning device.

For a device used in the digestive tract/gastric space, the device assembly 100 can be positioned within the body either by natural ingestion or the use of a delivery system (such as a catheter, endoscope, or other medical device). The delivery system can optionally comprise an oral dosage form, not illustrated, which facilitates the ingestion of a relatively large object. In other embodiments the system comprises a tether that allows manipulation or control of the placed construct from outside of the body. The assembly 100 can also be placed in the stomach by more invasive surgical or endoscopic procedures.

In FIG. 1A, the device 100 is shown immediately after being deployed within the stomach 2 and is ready to be activated. As noted herein, the device 100 can be deployed in the configuration shown. Alternatively, the device can be contained within a capsule or pill-type casing that allows for swallowing by a patient. Once swallowed, the casing will readily dissolve or break down resulting in the configuration shown. Once in place in the stomach, the assembly 100 begins to expand in order to occupy volume/space within the body. Expansion can occur via manual inflation, including hydration or other activation of a filler material (as shown optionally using a catheter, inflation tube or other delivery system), via absorption of body fluids, via remote actuation of a substance already located within the device assembly, and/or delivering of a fluid into the assembly, where the fluid itself causes expansion. Variations of the device also include a combination of such expansion means.

The variation shown in FIG. 1A includes a member 110 that extends from the device 100 to outside of the patient. In this variation shown, the member 110 comprises a fluid transport member that is fluidly coupled to an interior of the device 100 allowing for the delivery of substances and/or fluids within the device 100. FIG. 1A shows an exemplary fluid source 90 coupleable to a variation of a fluid transport member 110 such that the delivery of fluid causes a filler material 108 within the device to expand. In the illustrated example, the fluid transport member comprises a conduit. However, alternate variations of the devices described herein include fluid transport members that reside within the patient's body. Alternate variations of the device 100 also include members 110 that function as delivery or positioning systems to ensure proper placement of the device 100 within the body. Such delivery systems may or may not be fluidly coupled with an interior of the device. In variations discussed below, the device can include one or more fluid transport members that remain within the body but still convey fluid into the device 100 to allow the device to assume an active profile.

FIG. 1B shows one a partial cutaway view of an example of a device assembly 100 for use in occupying space within a body. In this variation, the device assembly 100 includes a material surface or skin 102 that forms a reservoir or pocket 104 capable of retaining a variety of substances, including but not limited to fluids, solid substances, semi-solid substances, etc. In the illustrated variation, the reservoir 104 holds a filler material 108 such as dehydrated hydrogel granules that can swell in size upon the addition of a fluid. However, any number of substances can be contained within the reservoir 104. Alternate variations of the device and/or method include assemblies that do not include a filler material; rather a filler material can be deposited within the reservoir 104 once the assembly is deployed. Alternatively, or in combination, the reservoir can be filled with a gas, liquid or other gel type substance.

In other variations, the device assembly 100 can include an empty reservoir that can be deployed into the body and subsequently filled with a filler material or other substance. For example, such variations can include a liquid filler material that is delivered to the reservoir through a conduit. The volume of liquid required to expand the device into a desired active profile can pre-determined. In some variations, the volume can be determined by measuring the back pressure in the conduit or pressure within the reservoir using any number of pressure detecting elements.

FIG. 1B also illustrates a variation of a sealable fluid path 112 coupled to and/or forming part of the fluid transfer member. In this example, the sealable fluid path 112 extends outside of the perimeter of the skin 102 of the device 100. Additional variations of the device 100 can include significantly shortened sealable fluid paths 112. In yet additional variations, the device assembly 100 can omit the sealable fluid path 112.

As noted herein, the skin 102 includes a release material 106 coupled thereto, where the release material 106 allows for initiating release of the assembly 100 from the body shortly after degradation, activation, or breakdown of the release material. Once the device assembly 100 is in the active profile, it can remain in the active profile for a pre-determined amount of time or until the patient experiences a desired therapeutic effect. To initiate release of the device assembly 100 from the body, an exogenous material, substance or stimulus is administered to the patient. The substance can comprise a fluid or other activating agent having properties that either directly or indirectly act on the release material to disrupt the barrier and allow the contents of the reservoir to be exposed to the body. For example, the exogenous substance can comprise a heated fluid that melts the release material. Alternatively, the exogenous material can change a temperature and/or an acidity of fluids in the stomach such that the enhanced properties of the fluids begin to act, either directly or indirectly, upon the release materials. In additional variations, the release material can comprise a material or materials that effectively form a barrier as discussed herein and are separated or disengaged by the use of an exogenous stimuli (e.g., a magnetic field, ultrasound, IR heating, coherent light, electromagnetic signals, microwave field, etc.).

FIG. 1B also illustrates a variation where the release material 106 is in the form that approximates shape and/or size of the casing used to deliver the device 100 (in this example the release material 106 is in a pill shape). One benefit of such a configuration is that the release material 106 can be positioned within the casing without excessive folding or bending.

FIG. 1C illustrates a sectional view of another variation of a device assembly 100. In this variation, the release material 106 binds or otherwise joins edges of the skin from within the reservoir 104. Such a configuration protects the release material 106 from the local environment of the body (e.g., fluids within the stomach or digestive tract). The release material can still be activated and/or degraded by the addition of the exogenous material to the body as described herein. However, positioning of the release material within the reservoir permits the skin 102 to serve as an additional layer of protection to prevent inadvertent release of the device assembly 100. The release material 106 can comprise a layer that binds edges of the skin together.

FIG. 1C also illustrates a variation of a sealable fluid path 112. In this example, the sealable fluid path 112 does not extend outside of the perimeter of the skin 102. Additional variations of the device 100 can include significantly shortened sealable fluid paths 112. In yet additional variations, the device assembly 100 can omit the sealable fluid path 112.

FIG. 1D illustrates the variation of the device 100 shown in FIG. 1A as the device assembly 100 assumes an active profile. An active profile includes any profile apart from a deployment state and where the profile allows the device to perform the intended effect of occupying volume or space within the body to produce a therapeutic effect. In the illustrated example, a physician or other medical practitioner delivers fluid via the fluid transport member 110, comprising a conduit 114 in this variation, and into the reservoir 104 causing a filler material 108 to swell. As noted herein, other variations include device assemblies without filler material where the conduit 114 simply delivers fluid and or other substances that allow the device assembly to achieve an active profile.

When using a conduit 114 that extends outside of the body, a physician can deliver a hydrating liquid, such as water or distilled water through the conduit 114. Generally, a pre-determined volume of liquid can be manually or mechanically pumped into the exterior end of the conduit wherein the volume of liquid is pre-determined based on a particular size of the device assembly or based on a desired active state. In some variations, the volume of liquid can also depend on the length of conduit.

The conduit 114 can be used to transfer a substance or into the reservoir 1014 of the device. In the illustrated variation, the conduit 114 transfers fluid from outside of the patient's body into the reservoir 104 after deployment of device assembly 100 within the body. Alternatively, or in combination, a fluid transfer member can comprise a wick type device that transfers liquids or other fluids from within the body to the reservoir.

FIG. 1E shows the device assembly 100 after it is inflated, expanded, or otherwise transitioned to achieve a desired active profile. A physician can monitor the profile of the device assembly 100 either using a scope positioned within the stomach (not shown) or non-invasive imaging such as ultrasound or a radiographic imaging. Alternatively, or in combination, the active profile can be achieved after a pre-determined volume of fluid, liquid and/or gas is delivered to the reservoir 104. Furthermore, variations of the device can include one or more markers (such as radiopaque markers) 116 allowing a physician to determine orientation and/or size of the device assembly 100.

As noted above, this particular variation of the assembly 100 includes a conduit 114 that is coupled to the skin 102 through the fluid path 112 and extends into the reservoir 104. Alternatively, a conduit 114 can be directly coupled to the skin. When the device assembly 100 achieves the active state the conduit 114 can be pulled from the device assembly 100. For those variations that employ a sealable fluid path 112, withdrawal of the conduit 114 causes the sealable fluid path 112 to collapse or be compressed thereby preventing the contents of the reservoir 104 from escaping from the device assembly 100. Alternatively, or in combination, the sealable fluid path 112 located within the reservoir 104 can be sealed due to the increased pressure within the reservoir. In other words, the same pressure within the reservoir 104 that causes expansion of the device 100 also causes the sealable fluid path 112 to close, compress or otherwise reduce in diameter to a sufficient degree that material is unable to escape from the reservoir through the sealable fluid path 112.

In certain variations, the conduit 114 is held in place in the sealable fluid path 112 by friction alone. Withdrawal of conduit occurs by pulling on the conduit in a direction away from the device 100. During the initial stages of this withdrawal activity the expanded device 100 generally moves upwardly with the conduit in the stomach, until the expanded device 100 reaches the esophageal sphincter. With the device assembly restrained from further upward movement by the sphincter, the conduit 114 may then be withdrawn from the fluid path and from the patient by additional pulling force.

Upon withdrawal of conduit 114 the fluid path effectively seals, as described herein, and prevents migration of fluids or other substances into and out of the reservoir. In certain variations the fluid path seals on its own after removal of a conduit or other member located therein. In additional variations, hydrostatic pressure and/or pressure caused by the expanded filler acting along the length of the fluid path can aid in sealing of the fluid path.

FIG. 1F illustrates a state of the device assembly 100 after a physician or the patient desires to initiate release the device assembly 100 from the body. As discussed above, an exogenous material 120 is delivered into the stomach (or other portion of the body as applicable). As the exogenous material 120 (or exogenously activated body fluids) engage the release material 106, the release material reacts to the conditions created by the exogenous material and begins to degrade, melt, break down, or otherwise become unstable such that the physical barrier of the skin 102 becomes compromised. As noted above, additional variations of the devices can be used with an exogenous stimulus in place of or in addition to an exogenous material. For example, the exogenous substance can directly act upon the release material such as providing a substance at an elevated temperature and/or PH level that causes disruption of the release material to allow the filler material to interact with the fluids in the stomach and/or to pass from reservoir into the stomach. Alternatively, the exogenous material can interact with fluids within the body to directly or indirectly activate and/or degrade the release material.

In alternate variations, the release material, or additional areas on the skin degrade or become unstable due to the passage of time in the normal gastric environment. In such cases, the additional areas can serve as a safety mechanism to ensure release of the device after a pre-determined period of time. For example, in the variation shown in FIG. 1F, one of the areas of release material 106 can be responsive to exogenous stimulus or exogenous materials while the other release material 106 can break down over time. Alternatively, or in combination, as shown in FIG. 1F an exogenous stimuli can be used in combination with the exogenous material 120 to cause disruption of the release material. In another variation, the exogenous stimuli 130 can be used to act directly on the release material 106 (without any exogenous material) to cause disruption of the release material 106 and to begin the process of releasing the device assembly 100 from the patient.

FIG. 1F illustrates the filler material 108 escaping from the reservoir 104 as the device assembly 100 decreases from its active profile to allow for passage of the skin 102 and filler material 108 from the body. In certain variations, the consistency of the escaping filler material 108 is similar to or closely approximates the consistency of a food bolus. The matching of the consistency of the filler material to naturally occurring particles that travels within the body ease the passage of the filler material 108 through the remainder of the digestive tract. In certain situations, the instability or degradation of the release material 106 allows bodily fluids to mix with the content of the reservoir 104, which liquefies the filler material and expedites reduction of the device assembly 100 from an active profile or state. Although not illustrated, as the device assembly reduces in profile, the peristaltic movement of the muscles in the digestive tract works to extrude materials out of the device 100, allowing for the passage of the skin 102 of the device 100 through the digestive tract until it is ultimately excreted from the body. Certain variations of the device assembly can be made to have a soft, lubricious and/or malleable or deformable configuration, wherein lubricious means wet and/or slippery to the touch, to aid in passing through the gastrointestinal tract, including swallowing. In other variations the device assembly may comprise an ingestible delivery system, not illustrated, wherein the delivery system facilitates swallowing the device assembly.

FIGS. 1A to 1F are intended to illustrate variations of devices and methods for occupying space within a patient's body, especially those devices for use within a gastric space. However, the principles described above can be used with any number of variations of the device as described below. As noted herein, combinations of different variations of devices, as well as the combinations of aspects of such variations are considered to be within the scope of this disclosure where such combinations do not contradict one another.

In the embodiment shown in FIG. 2 the construct 1000 is in a hydrated or active profile and comprises a generally oblate spherical shaped structure whose outer “skin” defines a material reservoir or pocket 1010. The reservoir 1010 is bounded by a thin, flexible material surface or skin 1013 that encloses an interior volume 1015 for retaining substances that maintain the construct in the active profile. In one such variation, the reservoir 1010 contains a filler material 1200, which may be a liquid or a semi-solid or gel-like material. In general, the volume of filler material 1200 is initially low, that is, when construct 1000 is in its initial, pre-deployment condition. The volume of filler material 1200 increases after the construct's deployment. Construct 1000 in FIG. 2 illustrates the fully expanded or active state but for clarity only a representative portion of filler material 1200 is shown.

The transition from initial, unexpanded state construct 1000 to the active state can be effected by increasing the volume of filler material 1200 enclosed in reservoir 1010. Additionally, the volume can be expanded through expansion and/or swelling of the filler material already inside the reservoir 1010. For example, as was described in commonly assigned U.S. patent application publication number US2011/0295299, one exemplary embodiment filler material 1200 in the initial state is a pre-determined volume of dry hydrogel granules. The dry hydrogel granules can swell, for example, between 10 and 400 times their dry volume when exposed to an appropriate liquid, generally an aqueous solution.

In the variation shown in FIG. 2, once a medical practitioner or user deploys of the construct 1000 into the stomach, the aqueous liquid in the stomach migrates into the reservoir 1010 and creates a slurry of liquid and substantially fully hydrated hydrogel. As is well known, hydrogels absorb water from their surroundings causing swelling of the hydrogel. In the embodiment of FIG. 2, the volume of dry hydrogel is pre-selected to have a fully swollen, unconstrained volume that slightly exceeds the volume of the reservoir 1010. Under constraint, hydrogels cannot swell to a greater volume than the limits of the constraining volume; however, constrained hydrogels can and do exert pressure against the constraint. Thus, reservoir 1010 becomes a structurally self-supporting structure, when filled with an excess of swollen hydrogel (that is, when the unconstrained volume of the swollen hydrogel is greater than enclosed interior volume 1015). In other embodiments, reservoir 1010 is filled and pressurized with other filler. In its expanded state, reservoir 1010 can be sufficiently elastic to deform under external pressure and returns to its pre-deformation shape when the pressure is removed. In yet additional variations, the filler material can be selected such that it hardens after a period of time to become its own skeletal structure or to support the skin. Such a filler can be selected to eventually degrade based on the environment in the stomach or digestive tract.

Assemblies 1000 under the present disclosure can comprise a material surface or skin 1013 that is substantially impermeable to liquids and/or gases. In these embodiments, filler material 1200 can be, respectively, a liquid or a gas. Additionally, filler material 1200 can be a fluid-swellable material such as hydrogel, which, when hydrated, becomes a solid, semisolid or fluid-like gel or slurry. As illustrated in FIG. 2, embodiments comprising a substantially impermeable skin 1010 further comprise a fluid transport member 1100 that allows for the migration of fluid through the skin. In some examples, as noted above, the fluid transport member includes a sealable fluid path that may or may not be coupled to an additional fluid conduit. In additional variations, the fluid transport member can include a localized liquid transfer member 1100 that is disposed in an orifice 1020 through the skin 1013 and facilitates the migration of fluid between the interior and exterior of reservoir 1010. One such example can be found in U.S. Provisional application entitled “Resorbable Degradation System” Ser. No. 61/723,794 filed on Nov. 8, 2012, the entirety of which is incorporated by reference herein

As noted above, in certain variations, where the device assembly 1000 comprises a substantially liquid impermeable material surface, a construct 1000 in the expanded active profile can remain in stomach or other portion of the body indefinitely until released. Therefore, as noted above, devices of the present disclosure can include a release material 1400, which allow the construct 1000 to reduce in size from the active profile and ultimately pass through the body. Such an active release material 1400 configuration allows for on-demand release of the construct. As noted above, once activated, degraded, or otherwise made unstable, the release material allows migration of filler material from the reservoir and device assembly. In some variations, activation of the release material opens a passage in the skin 1013 of the device 1000. Alternatively, or in combination, activation of the release material can result in reduction of the integrity of the skin forming the barrier about the reservoir. Once the barrier is compromised, the filler material can safely pass into the body. Regardless of the means, the activation of the release material and release of the filler material collapses the device 1000 leading to egress or removal of the device 1000 through the body (in this variation through the lower gastro-intestinal track). As noted above, variations of the devices described herein include a release material that is activated by exposure to an exogenous substance.

In certain variations, the device assembly 1000, in the active profile, comprises a highly oblate spheroid wherein the skin 1013 can be a thin, film-like material that is soft, tear-resistant, flexible, substantially inelastic, and non-self adhesive. Such features can be beneficial for a device that is to be compressed into a small oral dosage form for administration. In certain examples, the skin 1013 comprised a 0.0015 inch thick polyether polyurethane film. In a simple variation, an oblate spheroid can be created from skins forming an upper material surface and a lower material surface, wherein upper material surface and lower material surface are sealed to each other as shown by seam 1004 in FIG. 2. One such means for sealing the device 1000 comprises an ultrasonic weld around the periphery of adjoining materials. As will be described in more detail below, in a possible assembly method, the upper and lower material surfaces are formed as nominally identical, substantially disk-like shapes of material, welded in a band around most of their circumferences, the assembly is then inverted (turned inside out) through an unwelded section. Once the assembly is inverted, the welded material forms the seam 1004 that projects.

FIGS. 3A to 3E illustrate additional variations of device assemblies 100 having various active profiles. It is understood that the shapes shown in the illustrations disclosed herein are examples of possible variations of the device. FIG. 3A illustrates a device 100 having a donut shape (i.e., an oblate shape with an opening 103 in or near a center of the device assembly 100). FIG. 3B illustrates a device assembly 100 having a rectangular or square-like shape. FIG. 3C illustrates a triangular shaped device assembly 100 In one variation of the tunnel valve 1110, as illustrated in FIG. 5, the plurality of protrusions 132 that form the device assembly 100. The number and direction of the protrusions can vary from that shown. FIG. 3E shows a variation of a device assembly 100 having a crescent shape.

The devices shown in FIGS. 3A to 3E also show release materials 106, whether located on an interior of an opening 103 or on an exterior of the shape. The variations shown in FIG. 3A to 3E can also include the additional features of the device assemblies described herein.

Alternatively, the release material can comprise a filament, clip, band, cap, or other structure that mechanically closes the edges of the skin. Further, as described below, a source of stored energy, such as a loaded spring or compressed sponge or other material, may be included in the release assembly, where such kinetic energy is also released upon activation of the release material and which may improve the performance of such assembly.

FIG. 4 illustrates a variation of a fluid transfer member 1100 also having a sealable fluid path 1110 for use with the device assemblies described herein. In this example the fluid transfer member 1100 also includes an elongate fluid conduit, or tube, that passes through a tunnel valve that functions as a sealable fluid path 1110. The tunnel valve 1110 can be positioned in an orifice in the upper 1014 or lower 1016 material surfaces or in an opening in a seam 1004 of the device assembly. This variation of the tunnel valve 1110 comprises an elongate portion 1022 that extends within the reservoir of the device assembly. In some variations, the tunnel valve can extend beyond the seam 1004 or beyond the exterior surface of the device assembly as discussed above.

As illustrated in FIG. 4, a portion of the fluid transport member includes a tunnel valve 1110 that can comprise two layers sealed along their edges, forming an orifice 1020. In additional variations, the tunnel valve 1110 can comprise a tube structure having a single continuous wall that defines a passage therethrough. In yet additional variations, a tunnel valve can include more than two walls. Regardless of the configuration, the wall or walls of the tunnel valve are predisposed to occluding or blocking flow through the tunnel valve by obstructing the orifice or passage 1020.

The orifice 1020 forms a fluid path that allows a remainder of the fluid transport member 1100 to deliver fluids into the reservoir. In this variation the fluid transport member 1100 further comprises a conduit. However, as noted herein, the fluid transport member can comprise a wick type device or any fluid source that allows delivery of fluids into the reservoir of the device. As also noted herein, a variation of the device comprises an attachment of conduit 1100 to a portion of tunnel valve 1110, wherein the attachment may be direct or indirect and wherein, in some variations the attachment is releasable to permit conduit 1100 to be detached, withdrawn, or removed from the tunnel valve 1110. Withdrawal or removal of conduit 1110 from orifice 1020 permits the tunnel valve 1110 to prevent egress of fluids or other substances from within the reservoir. Sealing of the tunnel valve 1110 can occur via a rise in pressure within the reservoir. Alternatively, or in combination, a number of other mechanisms can result in sealing or closure of the orifice 1020 in the tunnel valve 1110. For example, in additional variations the surfaces forming the orifice 1020 can seal upon contact or the length of the tunnel valve 1110 combined with its flexible nature can simply make it difficult for substances, such as an expanded hydrogel, to travel through the elongated portion 1022 of the tunnel valve.

FIG. 4 also shows the conduit 1100 extending through the tunnel valve 1110 such that it extends into the reservoir. However, in alternate variations, the device end of conduit 1100 can remain within an interior of the orifice 1020 of the tunnel valve 1110. In such a variation a distal end of the distal portion of the fluid conduit remains within the elongated passage of the fluid tunnel and can rely on flow pressure to propel the liquid through a portion of the tunnel valve such that the fluid ultimately ends up in the reservoir.

In one variation of the tunnel valve 1110, as illustrated in FIG. 5, the tunnel valve 1110 shaped roughly as the capital letter T, wherein the vertical stem of the T comprises the elongate passage 1022 and wherein the crossbar of the T, in part, forms an increased attachment surface that can be attached to the skin as noted above. As may be seen in FIG. 5, tunnel valve 1110 can be disposed through an opening in the seam 1004. In other variations tunnel valve 1110 can be formed as part of the upper 1014 or lower 1016 material surfaces. That is, the templates that are used to cut the upper and lower material surface layers can include elongated tabs that correspond to the upper and lower layers of elongate passage 1022. The seams of said tabs may be sealed during the process of sealing the upper and lower material surface layers, leaving an unsealed, axially extended orifice in the center of the elongate tabs.

Some examples of materials used to form a tunnel valve include thin, film-like materials. For example, variations include tunnel valve materials that have properties similar to the material used in material surface or skin of the device. Additional materials include but are not limited to polyurethane, nylon-12, and polyethylene. In certain variations, Suitable materials typically have a durometer hardness of 80 Shore A or softer and are extruded with a glossy finish to enhance cohesion and tackiness. Layers of material in exemplary tunnel valves can be between 0.001 inch and 0.1 inch thick. In one example a tunnel valve included a thickness of 0015 inch. The length of the elongate portion 1022 that extends within the reservoir of the device assembly may be short, for example, 0.1 inch or as long as the diametric width of the device assembly.

As discussed above, variations of a device assembly include a release material that is coupled to a portion of the skin to form a barrier to retain substances within a reservoir of the device. FIG. 6A illustrates a partial view of a variation of an invaginated section 126 of a skin 102 of a device assembly 100. As discussed herein, the skin 102 can include a first surface 122 and second surface 124 joined at a seam 118. The seam 118 can include any number of enjoined sections that are intended to function as release areas 128. In the illustrated example, the release area 128 is bounded by an inwardly directed, or inverted section 126, of the skin 102. The particular illustrated embodiment of inverted section 126 is also known as the invaginated section 126, so named as it may comprise a tuck, fold, pucker, bulge, extension, etc. in the skin 102. Alternatively or in addition, the inverted section 126 can be formed within a first 122 or second 124 surface of the skin 102 rather than within a seam 118

The release area 128 of the invaginated section 126 ordinarily forms a passage that is fluidly sealed by a release material 106. The release material can comprise a mechanical closure (such as a staple-type structure or a filament that ties together the invaginated structure). Alternatively, or in combination, the release material 106 can comprise a temporary seal or other joining of the edges of the invaginated section 126. In additional variations, the release material can extend outwardly from an exterior surface of the skin. In some variations, the release material 106 is disposed on the invaginated portion 126 sufficiently close to the skin to be affected by a temperature increase caused by delivery of the exogenous substance.

In certain variations, the inverted section 126 forms a release area 128 that provides a passage to provide fluid communication between the reservoir and the exterior of the device assembly. This feature allows release of any fluids or material retained within the reservoir to allow the device to reduce in size and pass from the body. The opening can be located at the end of the passage, i.e., at the open edge of the material that is closed together. Alternatively, the wall forming the passage can be porous in an area beyond the point at which the inverted section 126 is bound (e.g., the area disposed inwardly relative to release material 106).

In additional variations, the inverted section 126 includes an energy storage element that encourages a rapid and more complete opening of the release area 128. As shown in FIGS. 6B and 6C, variations of the internal energy storage element 127 can include a solid structure, or a structure that allows passage of fluids. The energy storage element 127 can include a compressible elastic material, for example, a latex foam. In some variations internal energy storage element 127 is generally cylindrical with a diameter at least fractionally smaller than the diameter of the passage in the inverted section 126. As shown in FIG. 6B, when device 100 is deployed in the body, release material 106 is tied firmly around the inverted section 126 at the position of the internal energy storage element, thereby simultaneously sealing the invagination and compressing the internal energy storage element. The energy storage element can be a solid cylinder or can have a passage therethrough. The resilience of the elastic material in the internal energy storage element 127 creates a tensile force in release material 106 that is greater than the tension in the release material tie used to seal an invagination alone.

FIG. 6C illustrates the inverted section 126 after an exogenous trigger or inherent degradation causes release material 106 to cease restraining the inverted section 126. As illustrated, the release material structurally deteriorates to allow opening of the inverted section 126 and release the contents of the reservoir. The increased tension generated by the internal energy storage element encourages the release material to break apart sooner, more rapidly, and more completely than it otherwise would.

As noted above, the internal energy storage element 127 can be a compressible, elastic tube 127 in the form of a hollow cylinder having an axial fluid passage from one end to the other. The tube, in some variations, can be glued in place in inverted section 126. In additional variations, the elastic tube 127 can comprise a silicone material. When the release material 106 cinches around the area of inverted section 126 containing elastic tube 127, the internal passage of tube 127 compresses inwardly and forms a tight seal. Upon release, that is after release material 106 has been degraded by either an exogenous substance or by its organic temporal degradation, elastic tube 127 returns to its uncompressed state, which includes the hollow, open fluid passage (as shown by FIG. 6C).

One variation of an internal energy storage element is illustrated in FIG. 6C, where the internal energy storage element 127 is a hollow cylinder having an axial fluid passage from one end to the other. The tube can be glued in place in inverted section 126. In some embodiments elastic tube can be silicone. When filamentary release material 106 is cinched around the area of inverted section 126 containing elastic tube 127, the internal passage of tube 127A is compressed inwardly and forms a tight seal.

FIG. 6D illustrates an example of an inverted section 126 that is pleated or folded and restrained by a release material 106. The optional energy storage element, if used, is not shown in FIG. 6D for sake of clarity. However, variations of the devices can include energy storage elements that are located between folds or folded into the inverted section 126.

In another variation, not illustrated, the energy storage element is disposed outside of inverted section 126. An external energy storage element, for example a retaining ring, is used to increase the tension in the cinched and tied filamentary release material 106. The increased tension encourages the release material to break apart sooner, more rapidly, and more completely than it otherwise would. A suitable external energy storage element may be made using, for example, a special order, 5 millimeter diameter, Hoopster® retaining ring, available from Smalley Steel Ring Company, 555 Oakwood Road, Lake Zurich, IL 60047.

The release area 128 in each of the variations of the inverted section 126 is initially sealed or closed off by a release material that is coupled, directly or indirectly, to a portion of the skin to form a barrier to retain substances within a reservoir of the device. In many variations the release material is filamentary. Examples of release materials that are available in filamentary form can include Polyglycolide (PGA), Polydioxanone (PDS), Poly(lactic-co-glycolic acid) (PLGA), Polylactide (PLA), Poly (4-hydroxybutyric acid) (P4HB), Polyglactin 910, and Polycaprolactone (PCL).

In such variations, the release material in the expanded device assembly degrades over time by hydrolysis where the rate of hydrolysis varies with material selection and liquid filler pH. In variations wherein the release material is PCL the release material can also degrade by elevating the temperature of the release material since PCL softens, melts, and weakens above a pre-determined temperature. In some cases the pre-determined temperature is greater than normal body temperature. Accordingly, in such variations, the exogenous substance can comprise a heated fluid that can raise the temperature of the PCL without causing injury to the adjacent areas of the body. As the PCL release material degrades, the structural integrity of the joined region of the release section (such as the inverted section 126) decreases. In one example, the release material is a modified PCL, wherein the modification comprises lowering the melting point of unmodified PCL from its normal melting temperature to a human-tolerable temperature.

Examples of the release material can include poly(caprolactone) or PCL. In such variations, PCL softens, melts, and weakens above a pre-determined temperature. In some cases the pre-determined temperature is greater than normal body temperature. Accordingly, in such variations, the exogenous substance can comprise a heated fluid that can raise the temperature of the PCL without causing injury to the adjacent areas of the body. As the PCL release material degrades, the structural integrity of the joined region of the release section (such as the invaginated section 126) decreases. In one example, the release material is a modified PCL, wherein the modification comprises lowering the melting point of unmodified PCL from its normal melting temperature to a human-tolerable temperature.

For example, an on-demand degrading construct composed of nylon-12 can be constructed by first fabricating a 1″ circular annulus of 1.5 mil Pollethane, also known as 55DE Lubrizol 2363 polyether polyurethane (available from Specialty Extrusions Inc. of Royersford, PA, USA). A circular degradable patch of poly(caprolactone) (PCL) (with a modified melting point, T_(m), equal to ˜47° C.; available from Zeus Industrial Products of Charleston, S.C., USA) can be RF-welded to the Pellethane annulus, covering the hole, creating a T_(m)-modified PCL patch surrounded by a rim of Pollethane. The Pollethane rim can then be RF-welded to a sheet of nylon-12, which can then be used for further construction.

Examples of release materials can include biocompatible manufactured polymers. Table 1 is a compilation of the degradation properties of several biocompatible materials that can be extruded or otherwise manufactured in filamentary form and which also can be predictably degraded. Some of these materials, polyvinyl alcohol) are stable in dry environments but dissolve very quickly in moist environments. Some biocompatible polymers, for example co-polymers of methacrylic acid and methyl-methacrylate, dissolve in liquids having physiologically relevant pHs. For example, they remain stable at pH<7.0 but dissolve at pH>7.0. Other polymers, for example Poly(caprolactone), remain stable at typical gastric temperatures but melt in seconds at temperatures above a pre-determined melting point.

In some variations, polymers that degrade by gradual hydrolysis may be used for the release material. The degradation times of various polymers, under various degradation conditions, can range from about 2 weeks to about 6 months, where the degradation time depends on parameters such as degradation liquid pH, suture construction (e.g., stranded or monofilament), and filament diameter. In general, polymers last longest when exposed to distilled, neutral pH water and degrade more quickly when immersed in acidic or basic pH liquid.

The degradation times for several exemplary materials are tabulated in Table 1. The experimentally determined degradation times in the table were determined in simulated use conditions; that is, as illustrated in FIG. 6D, the release material 106 was coupled to an example or simulation of an inverted section 126 that is pleated or folded.

TABLE 1 Exemplary Release Material Properties Degradation Degradation Polymer Mode Condition Degradation Time Poly(glycolic acid) Gradual hydrolysis Exposure to ~ 2 weeks water or acid Poly(dioxanone) Gradual hydrolysis Exposure to ~ 1 to 2 months water or acid 1 PDO 0.9% benzyl 54 days alcohol 3-0 PDO distilled water 56 days 4-0 PDO distilled water 60 days 4-0 PDO 0.9% benzyl 62 days alcohol 3-0 PDO 0.9% benzyl 65 days alcohol Poly(lactic-co-glycolic Gradual hydrolysis Exposure to ~1 month acid) water or acid 3-0 PLGA distilled water 25 days Poly(vinyl alcohol) Rapid dissolution Exposure to any Seconds aqueous solution 4-0 Monocryl distilled water 27 days 2-0 Vicryl 0.9% benzyl 43 days alcohol 2-0 Vicryl distilled water 43 days 0 Vicryl distilled water 46 days 0 Vicryl 0.9% benzyl 48 days alcohol 1 Vicryl 0.9% benzyl 53 days alcohol 1 Vicryl distilled water 53 days Methyacrylic acid Hydrolysis; on- Exposure to Days at near neutral pH methyl-methacrylate co- demand pH- alkaline pH and minutes to hours at polymers dependent alkaline pH dissolution Poly(caprolactone) Hydrolysis; on- Exposure to heat 6 months at demand at temperatures less than temperatures melting point, seconds greater than 60° C. at or above melting point

As the release section opens the reservoir to the surrounding environment the opening provides an open path out of the device assembly. The open path allows the contents of the device assembly, such as the filler material, to become exposed to the gastric contents and freely to exit reservoir. When positioned within the stomach, normal gastric churning assists in emptying the contents of the device assembly allowing for the entire device along with its conents to pass from the body. In some variations, the membrane that forms the skin will provide little or no structural support. This configuration allows the body's natural squeezing strength to be sufficient to extrude any reasonably viscous substance out of the device assembly.

FIG. 6E provides a schematic illustration of another example of a device assembly 100 having a release material 106 located on a surface of the skin 102. One example of such a release material comprises a degradable patch 106 that, when degraded, opens the physical barrier surrounding the reservoir 104 to allow filler material 108 (swollen or unswollen) to exit the device assembly 100. The device assembly 100 comprises a skin material to which release material 106 can be joined (e.g. by heat sealing, RF-welding, impulse heating, or any other means). In certain variations, the release material/degradable patch 106 comprises a material or combination of materials that remains impermeable to water and hydrogel after deployment and can be degraded “on-demand” in response to an exogenous substance or in response to a condition created within the body being the result of the administration of the exogenous substance.

In one example, the release material can range from 25 microns thick; up to 2.5 millimeters thick. In another example, release material is a modified poly(caprolactone) with melting point T_(M)=47° C. (available from Zeus Industrial Products of Orangeburg, SC USA). In additional embodiments, degradable patch 106 may be poly(glycolic acid) or poly(L-lactide acid) (available from Poly-Med, Inc of Anderson, South Carolina).

FIGS. 7A and 7B show one example of an exploded, assembly view of a device assembly 100 (where a fluid transport member is omitted for the sake of clarity). As shown, the device assembly 100 can include a material skin comprising two layers of material that form an upper skin 122 and a lower skin 124. For clarity in FIGS. 7A and 7B, the exterior surface (i.e., the surface which will be on the exterior in the finished device) of each skin 122 and 124 is shown with shading; it will be understood that the skin material may be opaque, translucent, tinted, or transparent. As noted herein, the layers can be joined to form seam 118. Clearly, the presence of a seam is optional and some variations of devices under the present disclosure will not include a seam or will have similar types of joined regions of material to preserve the skin as a physical boundary for the contents of the reservoir. Again, the device assembly 100 is shown in the shape that eventually assumes an oblate spheroid shape. However, other shapes are within the scope of this disclosure. In one variation, the skin comprises substantially inelastic materials 122 and 124 that are joined around a perimeter leaving openings as discussed herein. It will be understood that, the shape of the device referred to as an oblate spheroid for descriptive purposes. In other embodiments wherein one or more devices may be joined to comprise a multi-bodied assembly, each individual device can be assembled from one or more sheets of film-like material that are cut to a pre-designed shape. FIG. 7A shows the device 100 in an inside-out configuration in mid-assembly. Seam 118 is only visible in this view on the inwardly facing surface of skin 124. As shown, the invaginated portion 126 can be secured with a filament release material 106 and/or a sealing release material 106 located within a release area 128. FIG. 7B illustrates an exploded view of the construct of FIG. 7A after the structure is inverted and a filler material is inserted into a reservoir formed by the skin materials 122 and 124. Seam 118 is again only visible in this view on skin 124 and has been folded inward during the inversion process.

As described above and further illustrated in the exploded views in FIGS. 7A and 7B, inverted section 126 can be a teat- or nipple-like structure in which release area 128 is a substantially narrow channel projecting inwardly into the reservoir of the assembled gastric device assembly 100. FIG. 7A illustrates the device assembly during the initial phases of its construction while FIG. 7B illustrates the device assembly after inversion of the assembly of FIG. 7A.

Variations of the devices described herein can include inverted sections 126 having any number of configurations. For example, as shown schematically in FIGS. 7C and 7D, an inverted section 126 is formed when two layers of material 102 are joined together to form a seam 118 having an extension in the V-shape of a cone- or funnel-like structure. FIG. 7C shows one layer of the material forming the outer covering or skin joined together at a seam 118 of the device. This V-shaped extension can then be cut along the line C-C to produce release area 128 that ultimately allows the inverted section to function to release contents of the reservoir.

FIG. 7D shows the structure of FIG. 7C after the device has been inverted such that the V-shaped extension is inverted into the area of the reservoir. In this variation, the wall of the inverted structure is formed by the seams 118 of the joined material. These seams 118 form the boundary of the release area or passage. In one variation the funnel-like structure 126 can be formed by incorporating an acutely angled, outwardly projecting, flap into two surfaces (e.g., an upper surface 122 and lower surface 124 of skin 102, see e.g., FIG. 7A). As noted herein, the end of the inverted structure 126 is temporarily secured with a release material 106. In the illustrated variation, the release material 106 is shown loosely positioned around inverted structure 126 for exemplary purposes and is not cinched about inverted section 126. Once cinched, the release material 106 prevents fluid flow through the passage 128 until desired or until a pre-determined period. It should be noted that filamentary release material 106 is typically cinched prior to deployment of the device body.

In certain variations the included angle for the flaps that form the inverted section 126 can be less than or equal to 90 degrees. Similarly, in some variations the included angle for the flap can be greater than or equal to 45 degrees, although lesser included angles are within the scope of this invention. Again, when device assembly 100 is inverted, as illustrated in FIG. 7D, the outwardly pointing tied flaps of FIG. 7C are converted into inwardly projecting funnel-like structure 126, comprising release area 128 with release material 106 that is now located inside the reservoir of the device assembly.

As noted herein, the release area 128 of inverted section 126 ordinarily forms a passage that is fluidly sealed by a release material 106. In those variations, where the release material 106 is a filament that ties the inverted section 126 closed to fluidly seal the release area 128, the inverted section 126 can include modifications to improve anchoring of the release material at its intended location. Such anchoring can improve retention of the release material on the inverted section.

For example, FIG. 7E shows a cross sectional view of an exemplary modification wherein the edges of the inverted section 126 have an indented or notched region 132 that serves as a defined location for the release material 106. In FIG. 7E, the region 132 is illustrated as having a “V” shaped notch but it will be understood that region B3 may have any convenient shape that increases the ability of the release material 106 to maintain the inverted section 126 in a cinched configuration, thereby preventing unintended release of materials within the reservoir. In another variation indented region 132 is a waist or smoothly-varying narrowing of inverted section 126. It should also be noted that filamentary release material 106 is illustrated as loosely encircling inverted section 126 for illustrative purposes only; in an operational system it would be cinched down tightly to seal release area 128.

FIG. 7F shows a second exemplary variation. In this example, the seams 118 bounding the inverted section 126 include one or more eyelet regions 136 or openings. Eyelet region 136 can be a widening of welded seam 118 near the end of inverted section 126. One or more small holes or eyelets 134 are disposed in the eyelet region(s), through which eyelets 134 filamentary release material 106 is threaded before being cinched and tied. Again, the filamentary release material 106 is illustrated as loosely encircling inverted section 126 for illustrative purposes only.

FIGS. 7G and 7H show additional variations of an inverted section 126 where the temporary seal/restraint can be improved by manipulations of inverted section 126. For example, as shown in FIG. 7G, the open end of inverted section 126 can be folded back on itself before release material 106 temporarily secures the inverted section 126. FIG. 7G shows inverted section 126 folded back upon itself, where the portion of inverted section 126 closest to skin 102 is a base section and the end portion of inverted section 126 is a folded section. Release material 106 can encircle both layers of inverted section 126 to tightly cinch the inverted section 126 and to seal release area 128. As previous figures, filamentary release material 106 is illustrated as loosely encircling inverted section 126 for illustrative purposes only. Although not illustrated in the figure, previous described techniques for securing release material 106 to inverted section 126 may be combined with folding inverted section 126 back on itself. For example, eyelet region described above can be added to both base section and the folded section. When inverted section 126 is folded the eyelets in base section 126A are aligned with the corresponding eyelets in folded section 126B, with filamentary release material 106 threaded through the thusly paired eyelets.

In another variation, as shown in FIG. 7H, inverted section 126 can be twisted about its elongated axis A before or after being secured with release material 106. As illustrated in FIG. 7H, inverted section 126 may be twisted several times to form a convenient working length of twisted material 138. Release material 106 is secured tightly anywhere within convenient working length 138. The twisted inverted section material underneath the release material 106 is compressed into tightly packed folds, thereby forming a highly effective seal even after the rest of the working length of twisted material is released and allowed to untwist. In some variations some of the length of inverted section 126 beyond tied release material 106 may be trimmed away.

As illustrated in the side view of FIG. 7I, in another variation, inverted section 126 is sealed with a normally-open, spring loaded mechanical clamp 2100, the clamp being held closed by release material 106. Clamp 2100 comprises two loops 2110A and 2110B. The loops are hinged at a common point 2120 and form a jaw that can clamp down on inverted section 126. The two loops that form the jaw are held in tight opposition by release material 106, illustrated as a filamentary material. In this exemplary embodiment, clamp 2100 further comprises a torsional spring 2130 disposed to open the jaws once release material 106 has been activated by the exogenous trigger or degraded by gradual hydrolysis.

In other variations inverted section 126 may be sealed with a normally-closed jaw clamp wherein the clamp itself comprises release material 106. In one embodiment the clamp comprises a single, typically molded, element with two distinct elongated jaw sections. A section of material is molded into a flexible region between the two jaws to serve as a hinge, allowing the two jaws to be disposed parallel to each other and in or nearly in contact along their thusly opposed, elongate surfaces. The ends of the elongate jaws are equipped with mating, molded latch features which, when engaged with one another, keeps the two jaws in their closely opposed configuration. In some variations the opposed, elongate surfaces comprise interdigitated features typically running parallel to the jaws elongated dimension.

Referring to the exemplary embodiments in FIGS. 6D, 7G, and 7H, the jaw clamp may be used in lieu of the filamentary release material 106 to seal inverted section 126. The open clamp may be disposed across inverted section 126 with its elongate jaws perpendicular to axis A in FIG. 7H. Closing the jaws down on material 102 seals release area 128 and the aforementioned latch features keep the jaws closed until release material from which the clamp has been made is activated by the exogenous trigger or is degraded by gradual hydrolysis.

FIG. 7J shows another variation of a device in which the inverted section 126 comprises a separate element that is later bonded to skin 102. In one variation, shown in FIG. 7J, a circular patch of skin material is formed into a nipple-shaped inverted section 126. As discussed above, the tip of inverted section 126 is removed to create release area 128 and the remaining material cinched closed with filamentary release material 106. The fabricated inverted section 126 is inserted through a hole cut into the upper skin 122, where the designation upper skin is only in relationship to the figure, with the filamentary release material 106 disposed in the interior of the device assembly, viz., in the reservoir. The inverted section 126 is bonded to upper skin 122 with either a bonding agent, e.g., a glue, or by other known bonding methods, e.g., RF welding.

In yet an additional variation, as shown in FIG. 7K, the inverted section 126 comprises an integral part of skin 102. During manufacture, inverted section 126 is formed into, for example, bottom skin 124 as part of the same operation that shapes bottom skin 124 into the desired hemi-ellipsoid. In some variations bottom skin 124 is joined to top skin 122 and inverted section 126 has its tip removed and is cinched and tied with filamentary release material 106. The device assembly is then inverted through a working space 160 in top skin 122 and the working space sealed. In other variations the inverted section is cinched and tied through working space 160, which is then sealed.

Material Surface or Skin

The type of material or skin will depend upon the intended application. In some variations, a skin will be chosen as a balance of selecting a sufficiently thick film-like material that has adequate strength. For example in some variations, tear resistance can be preferred to enable the finished construct to be compression into as low a volume capsule as possible. The inventors have determined that thin films with a thickness ranging from 0.5 mils to 4 mils are generally suitable. However, the devices described herein can comprise a greater range of thicknesses depending upon the particular application, including a range of thicknesses in different parts of the same construct. In some embodiments, the film-like material must be weldable or adherable to other materials such as might be used in valves 1110, filler material release mechanisms 1400, and/or attachment interfaces as described herein.

In additional embodiments, the film-like material exhibits low transmission rate of filler material, both before and after device expansion. In some embodiment the film-like material exhibits a low moisture vapor transmission rate. Additionally, some film-like material also exhibits high chemical resistance to the variable conditions encountered in the stomach. These conditions include low pH, high salt, high detergent concentrations (often in the form of bile salt reflux), enzymatic activities (such as pepsin), and the variable chemistries of chyme that depend upon the nature and content of consumed food. For those devices used in the gastric space, the material must also be comprised of biocompatible materials that can safely be in contact with the gastric mucosa for the duration of the treatment course.

The devices described herein can use numerous thermoplastic elastomers, thermoplastic olefins and thermoplastic urethanes that can be extruded or cast into single-layer or multi-layer films which are suitable for embodiments of the gastric device. Example base resins that may be employed include polypropylene, high-density polyethylene, low density polyethylene, linear low density polyethylene, polyester, polyamide, polyether polyurethane, polyester polyurethane, polycarbonate polyurethane, bi-axially oriented polypropylene, Polyvinylidene chloride, ethylene vinyl alcohol copolymer, and Ethyl Vinyl acetate. Some embodiments comprise single layer films whilst other embodiments comprise multiple layer films. Other embodiments consist of multilayer films including one or more tie layers to prevent layer separation.

In some embodiments, the film-like material may be coated with other materials. For example, in some embodiments hyaluronic acid coatings can be employed to improve softness and lubriciousness. In other embodiments, coatings such as Parylene® can be applied to improve the chemical resistance of the gastric mucosa-exposed film surface. In some embodiments, wax coatings, PVDC coatings, vacuum-metallization, or Parylene® coatings may be applied to the surface of the film to reduce its moisture vapor transmission rate.

In one example, the film-like material used comprised a 1.5 mil polyether polyurethane film. In other embodiments the film-like material is a 1 mil nylon 12 film or a 1.5 mil LLDPE film. In another example, the film-like material consisted of a multi-layered structure comprising an outer layer of polyurethane, a middle layer of PVDC or EVOH, and an inner layer of polyurethane.

Filler Material

Generally, a filler material that has a high swelling capacity and achieves a semi-solid consistency is useful to enable the finished construct to be compressed into as low a volume initial state as possible but still maintain rigidity once expanded. However, unless specifically noted, variations of the device can employ a number of different types or combinations of filler materials. During various experiments, it was determined that superabsorbent hydrogel polymers with a mass:mass swelling capacity of between 100 and 1000 are generally suitable, where a mass:mass swelling capacity of 100 is defined herein to mean that 1.0 g of dry hydrogel will absorb water and swell to become a semi-solid mass of 100.0 g.

Typically, suitable hydrogels swell maximally in the presence of distilled water and a number of these hydrogels also de-swell (releases bound water) in the presence of the variable environmental parameters encountered in the stomach. For instance, parameters such as pH, salt concentration, concentrations of emulsifying agents (often in the form of bile salt reflux), enzymatic activities (such as pepsin), and the variable chime chemistries, which depend upon the nature and content of consumed food can affect the swelling/deswelling behavior of certain hydrogels. Typical hydrogel swelling times range from between 5 minutes and 1 hour. In one variation, the hydrogel fully swells in under 15 minutes and fully de-swells in less than 10 minutes after exposure in certain environments. Many hydrogels are supplied with particle sizes distributed between 1 and 850 microns. In certain variations, gastric applications benefit from the use of hydrogel particle sizes distributed between 1 and 100 microns. In addition, the hydrogel must also be comprised of biocompatible materials that can be safely in contact with and excreted by the gastrointestinal tract. Examples of such biocompatible superabsorbent hydrogel polymers that possess swelling capacities, swelling times, and de-swelling times suitable for embodiments of gastric construct include poly(acrylic acid), poly(acrylamide), or co-polymers of poly(acrylic acid) and poly(acrylamide). Another such material that can be used as a filler material is a crosslinked poly(acrylic acid) with particle size distribution ranging from 1-850 microns and swelling capacity of 400.

Shapes

As discussed above, certain variations of the device approximate a highly-oblate spheroid comprising a diameter in the X-Y plane and a thickness along the Z-axis as illustrated in FIG. 2. In certain variations, the expanded dimensions of the device assembly can range from having a diameter between 2 inches and 10 inches. In another embodiment, the diameter of the construct is approximately 4.6 inches. The Z-axis thickness can range between 2 inches and 5 inches. However, the device assembly, unless otherwise claimed, is not limited to any particular dimension. The data below of construct parameters provides the experimentally determined dimensions of two constructs having the oblate spheroidal shape.

Parameter Construct 1 Construct 2 Unexpanded diameter (inches) 4.7  5.8′  Maximum swollen volume 300 ml 500 ml Expanded diameter (inches) 3.64 4.63 Expanded thickness (inches) 2.40 2.46

Liquid Transfer Valves

FIG. 8A shows an additional variation of a portion of a device assembly, in other embodiments liquid transfer member comprises a valve 150, wherein valve 150 is disposed in orifice 148 and provides a control over the fluid permeable path through otherwise impermeable material surface 102. In some embodiments valve 150 comprises a multilayer material structure composed of regions of permeability 152 juxtaposed against regions of impermeability 154, whereby fluid may transmigrate between the exterior and the interior of reservoir when the regions of permeability 152 and impermeability 154 are not pressed together in tight juxtaposition and whereby fluid is inhibited from transmigrating when the regions 152, 154 are pressed together tightly. In some embodiments valve 150 is self-closing. That is, valve 150 changes from allowing fluid transmigration to inhibiting fluid transmigration without external activation. In one embodiment valve 150 self-closes in response to the increasing pressure of the expanding filler material or increasing pressure within the reservoir, for example, swelling hydrogel pressing the regions 152, 154 sufficiently close together to form a barrier.

As noted above, the device assemblies described herein can include a wick-type structure that serves as a source to deliver fluids into the reservoir. One example of such a wick includes a filamentary material capable of conducting a liquid from one end to the other by capillary action. The wick can be used in a stand-alone manner or with a self closing valve.

In yet other embodiments liquid transfer mechanism 1100 comprises a mechanical valve. Mechanical valves of suitably small dimensions, comprising biocompatible materials, are well known in the art and are commercially available. A mechanical valve that serves as liquid transfer mechanism 1100 comprises a one-way or “check” valve design which allows fluid to enter reservoir 1010 but prevents fluid from exiting the reservoir. Alternatively, a mechanical valve that serves as liquid transfer mechanism 1100 may have a normally open state but which self-closes when internal fluid pressure is greater than external fluid pressure.

FIG. 9A shows another aspect of devices as described herein, for example, construct 200 can comprise one or more fluid transport members 208. As discussed herein, the liquid supply sources 208 are configured to allow fluid to enter the reservoir to combine with a filler material 202 disposed in an unexpanded device assembly 200. In some variations, the fluid transport member 208 can be coupled to a valve 210 that reduces, blocks or stops transport of liquid when filler material 202 is substantially hydrated as shown in FIG. 9B. Such a shut off ability is beneficial as it reduces the likelihood of filler material 202 becoming contaminated by gastric contents when the device assembly is in the active profile. Examples of such shutoff-mechanisms are described herein. FIGS. 9A and 9B also illustrate variations of the device assemblies 200 as including a tether 214 or other delivery system coupled to an attachment interface 216. FIG. 9A also illustrates two areas on the skin of the device having sections of release materials 206. As noted herein, the release material is responsive to an exogenous substance that causes degradation, melting, and/or other instability of the release material to allow exposure of the reservoir to the body. This allows the contents of the reservoir to pass from the device and eventually allows for the device to pass from the body.

FIGS. 9A and 9B also illustrate a device 200 having a delivery system 214, 216 attached thereto. The delivery system 214, 216 can comprise a filamentary tether 214 that is, generally, attached to the body of the device 200 via an interface 216. The attachment interface 216 can be designed as a structurally inherent part of the delivery system (i.e., it cannot be removed from the device body as a separate, stand-alone item). Alternatively, the interface 216 can be designed as an element that is added on to device 200.

Valves

FIGS. 10A and 10B illustrate one example of a valve driven by expansion of filler material 234 within a reservoir 236 of the device assembly 230. The valve 232 is positioned or otherwise disposed in an orifice 238 in the material surface or skin 232. This permits fluid to flow into or out of the reservoir 236 when the valve 232 is in an open configuration. In some variations, the orifice 238 comprises, typically, a small percentage of the total surface area of material surface 228. Material surface 228 is generally impervious or of limited permeability to the fluids in which device 230 is typically immersed. Orifice 238 can be an opening in the otherwise fluid-tight barrier formed by the skin 232.

FIG. 10A also illustrates a pre-determined amount of filler material 234 within the reservoir 236. In some variations, the pre-determined amount is generally measured by dry mass. The dry mass of filler material 234 is determined by the amount of filler material 234 needed to fill the known volume of the expanded device 230 when the filler material is fully hydrated. When expanded, the filler material applies a pressure within the reservoir 236, which provides a shape-restoring force that resists externally applied deforming forces.

FIG. 10A also shows valve 232 covering the orifice 238. This variation of the valve 232 includes one or more flow control layers 240 that aid in closing of the valve upon action by the filler material 234. FIG. 10B illustrates expansion of the filler material 234, which increases pressure against the valve 232 and closes the fluid path by compressing the flow control layers 240

Turning back to Fig. FIG. 10A, before filler material 234 expands, valve 232 is fully open; that is, it allows fluid to pass through the valve in either an inward or outward direction. On the other hand, after filler material 234 expands, typically via hydration, the valve 232 fully closes, as shown in FIG. 10B.

In some embodiments valve 232 comprises a filler material containment layer 242. Generally, containment layer 242 is at least partly fluid permeable and simultaneously able to contain filler material 234, in its dry or its hydrated state, within construct 230. In some embodiments filler material containment layer 242 is also a flow control layer; that is, a single layer in valve 230 can simultaneously be a part of the flow control function of valve 232 and perform the filler containment function of containment layer 240.

FIGS. 10C and 10D show another variation of a valve 232. In this example the valve 232 comprises more than one layer. As shown, this hybrid valve 232 comprises two demilunar flow control layers 248, each of the layers having a hybrid construction being permeable in some generally semi-circular (viz., demilunar) regions 250 and impermeable in other regions 252. The impermeable regions 252 of one layer are at least complementary to the permeable regions of the second layer; that is, where one layer has a permeable region the other layer has an impermeable region; generally there will be regions in which both layers are impermeable. Examples of the materials include a permeable patch comprising a polyester mesh and an impermeable semicircular patch comprising latex.

As illustrated in FIG. 10D, hybrid valve 232 comprises two substantially identical demilunar hybrid flow control layers, one on top of the other, wherein the two layers are oriented so that impermeable region 252 of a first hybrid control layer is aligned with the fluid permeable region 250 of a second hybrid flow control layer. By symmetry, impermeable region 252 of second hybrid flow control layer is aligned with the fluid permeable region 250 of first hybrid flow control layer. The two layers are affixed, typically with glue, around their periphery only, thereby allowing the central areas of the two layers to move apart freely.

It will be obvious to one of ordinary skill in the art that the circular shape of exemplary hybrid valve is a design choice made primarily to simplify alignment during assembly and installation. The principle of operation of a hybrid valve—that the two flow control layers have complementary permeable and impermeable regions—is independent of the peripheral shape of the valve or the orifice to which the valve shape and size is matched. For example, another exemplary hybrid valve is illustrated in FIG. 10E wherein each hybrid flow control layer 248 is generally rectangular and the impermeable region 252 and permeable region 250 are triangular.

Furthermore, permeable region 250 and impermeable region 252 in any individual flow control layer need not have identical shapes. For example, as shown in FIG. 10F, which shows an exploded view of a valve assembly, a permeable region in one individual flow control layer may be, for example, a circular region, and the impermeable region may be an annulus disposed around the circular permeable region. However the two layers of any one hybrid valve must at least have complementary permeable and impermeable regions; that is, when the two layers are overlaid there is no permeable area in communication with the exterior of the device.

In these exemplary embodiments of a hybrid valve, the flow control layer disposed on the internal side of the valve preferably can also function as filler material containment layer, with containment being achieved by the mesh comprising permeable patch. Alternatively, a separate innermost filler material containment layer must be added to the assembly.

In other embodiments, hybrid flow control layer is fabricated by joining a patch of permeable material and a patch of impermeable edge-to-edge, wherein the joint may be a butt joint, for example, or a lap joint, for a second example, wherein further the outer periphery of the edge-joined materials is designed to fill or cover orifice. In another exemplary embodiment of a hybrid valve the skin itself can serve as one of the flow control layers.

Wick Permutations

FIG. 11A illustrates another variation of a device 300 having a fluid transport member that comprises a fluid wick 302 that extends into a reservoir 304 of the device 300. Typically, a fluid wick structure conveys fluids from a wet end to a dry (or “drier”) end by capillary action. For example, if one end of liquid wick structure 302 is immersed in a liquid whilst the other end of liquid wick structure 302 is disposed in air, then the liquid moves through the wick structure 302 from the immersed end to the “in-air” end, at which end, typically, it will be absorbed by a filler material. The liquid will continue to flow through the liquid wick structure until such time that the “in-air” end is also immersed in liquid (that is, typically, immersed in a puddle of accumulated fluid).

Liquid wick structure 302 can optionally comprises a strip or thread of water absorbent material, for example, an absorbent matrix of cotton pulp (e.g. as in a sanitary napkin), polyvinyl acetal (e.g., as in an eye wick), polyvinyl alcohol sponge (e.g., as in ear wicks), or other materials typically used in, for example, surgical sponges. Alternatively, liquid wick structure 302 can comprise a strip or multi-strand thread of non-water-absorbing material, for example capillary-channeled nylon or polyester, wherein small capillaries are formed between the interior walls of the non-absorbent material. The wick can also comprise oxidized cellulose (available from Jinan Vincent Medical Products Co., Ltd, 122# East Toutuo Street Huangyan, Jinan, Shandong, China). Oxidized cellulose is known to absorb water but, as it is a polysaccharide, eventually solubilize after prolonged immersion in water.

In one variation, a wick structure 302 can have a substantially circular cross-section, the cross-section generally being greater than 2 mm in diameter and less than 8 mm in diameter, although both greater and smaller diameter wicks may be appropriate for large or small constructs respectively, the limits being determined by practicality and convenience rather than functionality.

Wick structure 302 is designed to convey fluid from the exterior to the interior of device 300, through an orifice in material surface 306; its length is preferably the sum of a convenient exterior segment, perhaps 2 cm, and an interior segment SKG2100 that is long enough to reach from orifice 308 to the furthest interior space in which filler material may be disposed. For some variations of the device, an interior segment of the wick 302 is approximately 6 cm, so a typical liquid wick structure 302 can be up to approximately 8 cm long. In other embodiments liquid wick structure 302 is between 4 cm and 12 cm in length. However, any range of wick length is within the scope of this disclosure.

In one variation, liquid wick structure 302 is inserted through an orifice 308 in device 300, where the device 300 is otherwise impermeable to fluid. Orifice 308 can be designed with a diameter that is approximately 50% of the diameter of liquid wick structure 302 to ensure that liquid wick structure 302 fits tightly and securely into orifice 308 when liquid wick structure 302 is dry. In some embodiments, orifice 308 may also have a diameter that is less than 50% of the diameter of liquid wick structure 302. The minimum diameter for orifice 308 is limited by constriction of the capillary action in liquid wick structure 302. That is, depending on the internal structure of liquid wick structure 302 and its material properties, too small an orifice will substantially shut off the transmigration of fluid through the liquid wick structure.

Alternatively, in some embodiments, orifice 308 may have a diameter that is greater than 50% of the liquid wick structure diameter, particularly if liquid wick structure 302 is being securely held by other means. With a large (greater than 50% orifice of the liquid wick structure diameter), liquid wick structure 302 can be heat-sealed, glued, or otherwise affixed in place in orifice 308 to prevent it from being displaced from its operational disposition.

As illustrated in FIG. 11B, when the construct, or at least the exterior segment of liquid wick structure 302 is immersed in a liquid, liquid is initially drawn into the absorbent wick material of liquid wick structure 302 and is further drawn from the wet wick material toward the dry wick material until interior sement of liquid wick structure 302 is substantially saturated. Liquid, on reaching the surface of liquid wick structure 302 (and in particular the end of interior segment), can be shed by dripping or it may be drawn off by contact with the absorbent, dry filler material. Filler material 306 swells as it absorbs liquid. The pre-determined quantity of dry filler material, when fully expanded, fills the construct to a slightly positive pressure and surrounds interior segment in a hydrated mass 234. This mass is the functional equivalent of a liquid bath. With both ends of liquid wick structure 302 are immersed in fluid, the liquid wick structure's capillary action stops or slows considerably, thereby ending fluid movement between the exterior and the interior of construct 300.

As illustrated in FIG. 12A, some exemplary embodiments of liquid wick structure 302 is fluidly coupled to a secondary, interior bag, pouch, or other container 310 to ensure that interior segment of the wick 302 is in direct contact with filler material 234 located within the container 310.

As filler material 234 swells, the container 310 releases filler material 234 into the reservoir of the device 300, where it continues to receive hydration from liquid wick structure 302. In one embodiment, illustrated in FIG. 12A, secondary bag 310 is water soluble, dissolving quickly as the partially hydrated hydrogel swells within it. In other embodiments secondary bag 310 comprises one or more weakened seams, the weakened seams splitting open as the hydrogel swells against it. In yet other embodiments, the entire secondary bag 310 comprises a structurally weak, permeable material, unable to contain the pressure of the swelling hydrogel. In yet other embodiments, secondary bag 310 comprises seams closed with sutures, the sutures being either inherently weak or water soluble. Any portion of a wick can be coupled to a container, not just the ends of the wick. For example, a wick can be folded such that the folded end is positioned within the container.

The wick 302 can be held in place within the container 310 as described above for the orifice. Alternatively it may be sealed closed by heat-sealing, gluing, or other means so that the tip of interior segment is disposed in direct contact with filler material 234.

In some embodiments, liquid wick structure 302 may be fabricated from a material that dissolves or degrades in liquid comparatively slowly relative to the time it takes for the filler material to fully expand. The material selected for this embodiment maintains its integrity and wicking ability long enough to fully hydrate filler material 234 but then degrades and disappears once the filler material is fully expanded. Examples of such materials include thin, cellulose-derived, porous woven or nonwoven materials and ‘ropes’ made of smaller tubes, including combinations of nanotubes.

FIG. 12B illustrates another embodiment of a device 300 having multiple liquid wick structures. This embodiment comprises a dual wick structure in which a single wick structure 302 delivers fluid into the reservoir through both ends. As shown, a wick is threaded through both sides of the skin of the device so that the wick is exposed on both sides. These two exterior wick segments absorb fluid and convey the fluid between an exterior of the device and the reservoir. Clearly, two or more wick structures can be used rather than both ends of a single wick structure.

As shown in FIG. 12C, in other embodiments the interior segment of a single liquid wick structure 302 is divided into two or more sub-segments. Sub-segments of the wick structure 302 can be directed to different locations in the reservoir of the device to distribute hydration fluid 1105 more efficiently or, as discussed above, each end can be directed to a secondary container.

In another aspect, a wick structure 302 can be affixed to a portion of the interior of the reservoir as illustrated in FIG. 12D. As shown above, the wick initially extends outside of the device. Upon swelling of the filler material, as the device expands, the section of the wick that is initially outside the device is pulled into the interior of the device assembly because it is affixed or secured to the interior of the reservoir.

Clearly, variations of the wick structure can be combined with other aspects and features described herein. Moreover, any embodiment disclosed herein can be combined with aspects of alternate embodiments or with the embodiment itself. For example, the wicks described herein can be combined with the valve mechanisms described herein and/or can be combined with the release materials discussed throughout this specification.

FIG. 13A illustrates a variation of a tunnel valve as discussed above. As shown, the tunnel valve forms a sealable fluid path that prevents material from escaping from the interior of the device. FIG. 13A illustrates an example of a device with a tunnel valve forming the sealable fluid path. As shown, device assembly 326 contains a valve member 330 comprising a liquid impermeable material that can be securely joined to the skin 328 in any manner conventionally known or by those discussed herein (including, but not limited to gluing, welding, heat sealing, or other means). Examples of materials useful for the tunnel valve include polyurethane, nylon-12, and polyethylene. The tunnel valve 330 can include any number of fluid transport members 332. In the illustrated variation, the valve is coupled to a conduit. However, variations include a wick type device located within the tunnel valve.

FIG. 13B shows a cross sectional view of tunnel 330 taken along line 13B-13B of FIG. 13A. As shown the tunnel valve 330 forms part of the fluid transport member 332 allowing transport of fluids between the interior/reservoir and interior of the device assembly. In certain variations, the tunnel valve 330 can be detachable from the remainder of the fluid transport member 332. Upon removal, the layers of the tunnel valve 330, as shown in FIG. 13C, close to an extent that the tunnel valve effectively closes and prevents migration of the filler material from the reservoir. In certain variations, the tunnel valve 330 fully closes, while in other variations, the tunnel 330 can remain slightly open. Variations of tunnel valves include assemblies of an extruded tube or two layers that are joined by gluing, welding, heat sealing, or other means at their two edges. In some variations, the tunnel valve has a wall thickness between 0.001″ and 0.1″. One example of a tunnel valve included a thickness of 0.0015″. In additional variations, tunnel valves can be flexible, compressible and/or deformable. In additional variations, layers of the tunnel valve can be reopened by the passage a structure (e.g., a conduit or other fluid transport structure).

As noted above, the tunnel valve allows for detachment of the remainder of the fluid transport member at any time, but typically once a sufficient amount of fluid is delivered to the device. Removal can occur via applying tension to a portion of the fluid transport member. Variations of the tunnel valve can employ permeable membranes, filter, or valves placed at the end of the tunnel valve to prevent dry hydrogel or other filler materials from entering the tunnel and affecting the ability of the tunnel valve to seal. In some embodiments, the membrane or filter may comprise a permeable fabric such as polyester, nylon, or cellulose. In other embodiments, a valve is placed at the end of tube comprised of a one-way duckbill or umbrella valve (available from MiniValve of Oldenzaal, Netherlands). Alternatively, or in addition, filler material 234 can be contained in a container as discussed above, which prevents the filler material from entering the tunnel valve and swelling upon infusion of liquid, thereby clogging the valve.

In additional variations, as shown, for example, in FIG. 13D, a portion of the tunnel valve extends outside the device assembly to form an external section 1110B. In some variations, as shown in FIG. 13G, external section 1110B terminates with two unjoined flaps, upper flap 1028 and lower flap 1026. In some examples, external section 1110B is typically between 0.1 inch and 0.5 inch long.

In some variations the tunnel valve comprises retaining elements to releasably hold the conduit in place throughout deployment of the device assembly. FIG. 13D illustrates one embodiment for retaining the conduit in a partial cut-away view from the interior of the device assembly. Tunnel valve 1110 comprises an interior section 1110A, which section is disposed inside the device assembly, and an exterior section 1110B that extends outwardly from the exterior of the skin. Tunnel valve 1110, as described above, is typically formed by sealing the edges of two layers of membrane material to form sealed seams 1024. In some variations sealed seams 1024 extend all the way to a proximal end 1110B1 and/or a distal end 1110A1 while in other variations the edges of the two layers may be unsealed for some length inward from proximal end 1110B1 and/or distal end 1110A1. The relative lengths of the interior and exterior sections of tunnel valve 1110 have been distorted in the figure for clarity purposes. Typically exterior section 1110B is just long enough to accept conduit 1100. As has been discussed, conduit 1100 is inserted into orifice 1020 prior to deployment of the device assembly and is used to deliver fluid to the reservoir therein to expand device assembly. Conduit 1100 must remain disposed in tunnel valve 1110 until enough fluid has been delivered to the device assembly to make it too large to inadvertently pass through the pylorus while at the same time conduit 1100 must be removable from the device assembly once its deployed profile has been achieved. Further, it is desirable that conduit 1100 also be useful for retrieving the device assembly from the stomach or esophagus in the case of an aborted deployment. In such an aborted deployment the conduit must be held in the tunnel valve with enough resistance to withstand the drag on the unexpanded device assembly as it is retrieved upwardly through the esophagus.

A suture 1032, which may be inserted through either or both of interior section 1110A or exterior section 1110B, is designed to hold the conduit in the tunnel valve under a wide range of extractive force. As illustrated in the figure, suture 1032 is stitched through the two layers of the tunnel valve, simultaneously passing through conduit 1100. The suture is tied to itself on the exterior of tunnel valve 1110. The small punctures in conduit 1100 and tunnel valve 1110 through which the suture passes are too small to allow any significant loss of liquid filler.

Once the device assembly has assumed its deployment profile conduit 1100 must be withdrawn from tunnel valve 1110. Conduit 1100 is released from tunnel valve 1110 by the controlled, on-demand degradation of suture 1032. As is discussed above certain suture materials can be dissolved or structurally weakened by exposure to specific exogenous agents not normally in the gastric environments, or not in the gastric environment in high enough concentrations to degrade the suture during the deployment time period. For example, poly(caprolactone) [PCL] softens, melts, and weakens above a pre-determined temperature, T_(M). In some cases the pre-determined temperature can be designed to be greater than normal body temperature but lower than human's physiologic pain threshold. In such a case, a PCL suture can be degraded by infusing heated liquid (above T_(M)) through conduit 1100 at the end of the deployment period or by having such liquid consumed orally.

In order to avoid over-filling the device assembly when the heated liquid is infused through the conduit the hot liquid infusion must start at after a pre-determined volume of un-heated liquid filler material has been infused, where the known capacity of the device assembly, the volume of fluid residual in the conduit, and the thermal capacity of the system are all incorporated into the determination. It should be noted that if the initial infusion of hot liquid fails to release the conduit by melting the suture, liquid can be withdrawn up the conduit to slightly reduce the volume of the device assembly and a second charge of hot liquid infused.

In another variation, as depicted in 13E and 13F, conduit 1100 is detachably joined to one or both double layer sealed seams 1024 of tunnel valve 1110 with a loop of suture material 1032. Suture loop 1032 comprises a single long loop which starts and ends at the proximal (e.g., patient's mouth) end of conduit 1100. The loop starts at the proximal end, runs down the interior of conduit 1100, and exits the conduit at a small orifice 1036 that transverses the wall of conduit 1100 near the proximal end of exterior section 1110B. After exiting from orifice 1036, the suture passes through one or two eyelet holes 1034 in sealed seams 1024 before returning to orifice 1036. The suture completes its loop by running back up the interior of conduit 1100. The two ends of suture loop 1032 are retained at the proximal end of conduit 1100.

Suture loop 1032 is installed during the manufacture of the device assembly and remains disposed in conduit 1110 during infusion of the liquid filler material. Conduit 1110 cannot easily be pulled out of tunnel valve 1110 while suture loop 1032 is in place. Once the device assembly has assumed its deployment profile, one end of suture loop 1032 may be released while the other end of the loop is pulled outwardly. When at least half the length of suture forming suture loop 1032 has withdrawn from conduit 1100, the loop is known to be unthreaded from the eyelet hole(s). Freed from the eyelets, conduit 1100 can then be withdrawn from tunnel 1100.

In some embodiments suture loop 1032 of FIGS. 13E and 13F may be made from PCL, in which case conduit 1110 may also be released by melting suture loop 1032 through the infusion or ingestion of hot liquid, as described above.

Another variation of fluid transport member 1100 is illustrated in FIG. 13G. In this variation sealed seams 1024 stop short of proximal end 1110B1, leaving two flaps of material, upper flap 1028 and lower flap 1026, where upper and lower are arbitrary designations relating only to the figure. Upper flap 1028 is prepared with a rip-off tab 1030, which comprises the most proximal section of upper flap 1028 and which is distinguished as the region sectioned off by a tear line 1038 of diminished tear-strength material. The tear-strength of tear line 1038 may be reduced, for example, by perforations, physical thinning, or chemical application (e.g., partial de-polymerization). In some variations the tear-strength of tear line 1038 is between 1 and 1.5 lbs. while other variations may have tear-strengths between 0.5 lbs and 2.5 lbs.

As illustrated in the figure, conduit 1100 is attached to rip-off tab 1030 at spot location 1040, where such attachment may be accomplished, for example, by gluing, melting, or ultrasonic welding. In this variation conduit 1100 is detached from tunnel valve 1110 by pulling outwardly on conduit 1100 with enough force to separate rip-off tab 1030 from upper flap 1028 along tear line 1038. Although depicted examples show only a single rip-off tab 1030, additional variations include two or more rip-off tabs, one such tab on each of the two flaps, wherein conduit 1100 is attached to both tabs.

In some embodiments, as depicted in the top view of FIG. 13H, depositing a fluid swellable substance 1046 between the layers of the tunnel valve may enhance the sealing effectiveness of tunnel valve 1110. The swellable substance generally remains unswollen while the conduit 1100 is installed in the valve. After conduit 1100 removal, swellable substance intercepts any liquid or semi-liquid filler material from the reservoir that migrates between the two layers of the nominally sealed valve. The swellable substance swells in response to any liquid component in the intercepted filler material, thereby blocking further filler material migration through the valve.

The swellable substance 1046 is typically superabsorbent poly(acrylic acid) hydrogel granules or superabsorbent poly(acrylic acid) hydrogel fibers. The swelling ratio of these substances (the mass of water absorbed for every gram of substance) is typically greater than 10.

In other embodiments, as depicted in FIG. 13H, orifice 1020 is tapered in one or more regions 1042, 1044, where the dashed line A-A′ indicates the skin of the device assembly. The region between the two tapered regions forms a pocket into which the swellable substance may be disposed. In embodiments with only one tapered region the region will typically be disposed near distal end 1110A1 and the swellable substance 1046 will be disposed to the proximal side of the tapered region. Tapered regions 1042 and 1044, may have a design diameter so that the conduit 1100 fits snuggly through the tapered region. The tapered region can then prevent the liquid filler from reaching the swellable substance while conduit 1100 is in place. The width of the tapered region is typically the outer diameter or width of the conduit 1100.

In some embodiments the seal of valve 1110 may be enhanced mechanically, as illustrated in FIG. 13I. In this exemplary embodiment a spring-loaded closure device 2000 is disposed on elongate portion 1022 of valve 1110. Closure device 2000 comprises two, U-shaped loops 2010A, 2010B, loops 2010 in this exemplary embodiment being connected at a hinge axle 2015. Each loop 2010 comprises a width comparable to the width of elongate portion 1022 and a length, L, which is the length of each loop 2010 extending from hinge axle 2015. For clarity, the loops are illustrated with exaggerated lengths.

Device 2000 further comprises a spring 2020 or similar energy storage element. Loops 2010, hinge axle 2015 and spring 2020 are configured to allow spring 2020 to drive loops 2010 into generally adjacent alignment by rotating one or both loops around hinge axle 2015, as indicated by arrow A in FIG. 13I.

During deployment, conduit 1100 is disposed within orifice 1020, typically extending through substantially the entire length of elongate portion 1022. As previously noted, in some embodiments conduit 1100 extends beyond the end of orifice 1020 (as illustrated in FIG. 13I). Closure device 2000 is disposed in its “open-flat” configuration on or around elongate portion 1022, whereby elongate portion 1022 is threaded through closure device 2000 by passing above loops 2010 and below hinge axle 2015.

Elongate portion 1022 is, by design, stiff enough to hold closure device 2000 in its open-flat configuration during deployment. It will be noted that elongate portion 1022 is stiffened during deployment by the presence of conduit 1100 since, as described herein, elongate portion 1022 is fabricated with two thin layers of a membrane-like material designed to collapse upon themselves while conduit 1100 must be rigid enough to provide an open fluid channel from a patient's mouth to his stomach.

After deployment, conduit 1100 is withdrawn from orifice 1020. Once the end of conduit 1100 passes the crossbar of loop 2010A, elongate portion 1022 is no longer stiff enough to retain loop 2010A in its open-flat configuration. Loop 2010A is rotated by torsion spring 2020 in the direction of arrow A, wrapping the distal end of elongate portion 1022 around hinge axle 2015 in the process. Loop 2010A continues rotating until it rests against loop 2010B, simultaneously pressing and sealing the doubled over elongate portion 1022.

In an alternative exemplary configuration, illustrated in side-view in FIG. 13J, closure device 2000 may be used as a spring clamp only, without the doubling over functionality discussed above. As shown, during deployment closure device 2000 is disposed in its open-jaw configuration, with elongate portion 1022 inserted into an open jaw 2012 formed by loops 2010A and 2010B. During deployment conduit 1100 inside elongate portion 1022 is stiff enough to hold jaw 2012 open; when conduit 1100 is withdrawn, the force of torsion spring 2015 closes jaw 2012, sealing elongate portion 1022.

In another embodiment, not illustrated, an elastic ring provides the mechanical assistance for enhancing the seal of valve 1110. The ring is disposed around on elongate portion 1022 of valve 1110. The ring's material properties and dimensions are selected to substantially seal the tunnel valve when the valve does not contain conduit 1100. However, when conduit 1100 is positioned within the tunnel valve, the rigidity of the conduit resists the sealing force of the elastic ring. The elastic ring may be composed of any elastomeric material that is known to be biocompatible. Examples include silicone, polyurethane, and latex.

Delivery System

As shown in FIG. 14, in certain variations, the device assembly can be compressed to fit within an oral dosage form 352 such as a pill, capsule, sleeve, or other dosage form that enhances the ability of positioning the device via ingestion or swallowing without the aid of another medical device. In such a case, the device 350 is contained within the oral dosage form 352 and can optionally include a tether 356. It should be noted that the conduits described above can also be used as a tether or vice versa. In any case, the tether 356 allows for controlling the deployment location of the device 350 within the gastrointestinal tract by manipulation of the tether 356, and finally completing the administration procedure by releasing control of the device 350, either by releasing the tether 356 for the patient to swallow or, more typically, by detaching the tether from the device 350 or oral dosage form. FIG. 14 also shows a tether 356 as having two ends to allow for greater control in positioning the device 350.

In accordance with the delivery method, a medical practitioner, typically a medically trained agent such as a physician, physician's assistant, or nurse, administers the tethered, encapsulated payload to a mammal, herein referred to as the patient. The method comprises the simultaneous steps of directing the patient to swallow oral dosage form while controlling the tether. In some embodiments controlling the tether comprises the use of a tube to transport liquid into the device, the method also includes infusion of liquid through the tube using a syringe, pump, or other liquid delivery means. Generally, the step of controlling the tether comprises, firstly, ensuring that the tether's proximal end is retained exterior to the patient and, secondly, assisting the patient by feeding the tether into the patient's mouth and throat at a rate compatible with the ingestion of the oral dosage form 352. That is, the agent typically adjusts the feed rate of the tether so the progress of the oral dosage form 352 down the esophagus is not impeded by tether-induced drag while at the same time the patient does not feel the tether is accumulating in his or her mouth. In additional variations, the medical practitioner can also use the tether by securing the section of the tether located outside of the patient's body (i.e., to a fixture in the room or to a part of the patient).

The method further comprises an optional step of controlling the delivery distance of the device. The delivery distance is, essentially, how far into the gastrointestinal tract the device is permitted to travel. Typical devices are designed to be deployed in the stomach although some devices may be designed to reach only the esophagus whilst other devices can be intended to reach the pylorus or beyond. The step of controlling the delivery distance is best accomplished with a device attached to a marked tether, whereby the length of the ingested tether corresponds to the instantaneous delivery distance, which length being directly readable from a marked tether. Part of this optional step of controlling the delivery distance is stopping the further ingestion of the tether.

In certain variations, the oral dosage form 352 dissolves upon reaching the stomach and the fluids therein. Once free from the oral dosage form, the device 350 is free to expand into deployed state or an active profile. Alternatively, device 350 expands into its active profile upon infusion of a hydrating fluid through the fluid transfer member.

Filler Material Release

One of skill in the art will note that the human GI tract is unique among the abdominal viscera as it is periodically exposed to very cold and hot substances during routine alimentation. For instance, the temperature of the stomach is known to increase to 44° C. after ingestion of a hot meal heated to 58° C. but quickly return to core body temperature (37-39° C.) in 20 minutes. Moreover, the temperature of the stomach can reach as high as 48° C. for between 1-2 minutes if 500 milliliters of 55° C. tap water is consumed rapidly (under 2 minutes) on an empty stomach. Thus, a biocompatible material that could be eliminated by melting would ideally remain stable at core body temperature (37-39° C.) but melt in response to a planned intervention that raised the temperature in the vicinity of the biocompatible material to the material's melting point. In the GI tract, such a material would have to withstand daily fluctuations in gastric temperature (e.g. after ingestion of a hot meal) and remain stable at temperatures between 37° C. and 44° C. but melt in response to a planned intervention (e.g. consuming 500 milliliter of 55° C. tap water).

In some examples it was noted that one material, polycaprolactone (PCL), has been extruded into a strong monofilament (Japanese publication JP-A05-59611 A) and has a natural melting point of 60° C., a melting point that is probably not safely usable in human stomachs. However, PCL can be modified to lower its melting point to more physiologically acceptable temperature. Moreover, the modified polymer can still be extruded into a strong monofilament suitable for suturing and stitching or a film suitable for heat welding to a membrane. PCL filamentary material with reduced melting temperatures (T_(M)) is available from Zeus Industrial Products of Orangeburg, SC, wherein 60° C.>T_(m)>45° C. by specification.

Delivery of Thermal Exogenous Substance

In some variations the degradable material used as release material 106 is allowed to degrade at its natural degradation rate in the mammalian gastric environment. In other variations, degradation is triggered or effected by the intentional introduction of an exogenous substance 120. In additional embodiments, exogenous substance 120 is introduced orally and at least partially in a liquid format into the stomach. In the stomach, the exogenous substance 120 mixes with the resident gastric fluid to become an immersing fluid that substantially bathes the construct. Alternatively, the exogenous substance 120 may be introduced into the stomach in a solid state, as in a tablet or capsule, typically accompanied by a liquid, whereby the solid is dissolved and becomes the immersing fluid, particularly when mixed with gastric fluids. In certain embodiments extra-corporal stimulation of the exogenous substance 120 may be used.

In many variations, the release material comprises modified PCL material, either as a thin film for degradable patch or as a filamentary material. In general, modified PCL melts at a specified melting temperature, T_(M) and the temperature of the stomach, T_(S), remains below T_(M). The exogenous agent for PCL, therefore, comprises an elevated temperature liquid—at temperature T_(L)—which raises T_(S) above T_(M). The exogenous agent temperature T_(L) needed to raise T_(S) above T_(M) is based on the design details of entire system; that is, the means of delivery of exogenous substance 120, the design of release material (that is, for example, stitches, patch or knot), and the specified melting temperature, T_(M), of the modified PCL.

For example, an intragastric construct comprising T_(M)=48° C. modified PCL will degrade after the rapid ingestion of a large volume of water with T_(L)=55° C. Clearly, the location of the PCL release material may affect the rate and/or temperature at which the PCL degrades. The extra-corporal exogenous substance 120 temperature T_(L) is higher than the melting temperature of the PCL to account for cooling of the formulation during transit to the stomach and due to mixing with the existent stomach fluids and for the placement of the release material. In one example, it was found that the rapid ingestion of approximately 500 milliliter of 55° C. water elevates stomach temperature T_(S) to at least 48° C., high enough to dissolve/degrade the modified PCL and allow the device to open and release its hydrogel contents.

In another example, an intragastric construct comprising with T_(M)=50° C. modified PCL will degrade after rapid endoscopic infusion of 500 milliliter tap water with T_(L)=65° C., a temperature that is too hot for comfortable oral ingestion but which is tolerated by the stomach when the liquid is delivered directly to the stomach. Alternatively, the exogenous substance 120 may be delivered directly to the stomach via a nasogastric tube, again circumventing the comfort limitations of oral ingestion.

In another variation, an exogenous substance can be used to raise the temperature or otherwise change the conditions of bodily fluids to effect release of the device. Additional variations allow for the use of an exterior energy source to raise the temperature of the area surrounding the device. For example, a patient can ingest a sufficient volume of fluid, followed by the application of an external energy source (e.g., radiofrequency or ultrasound) to the exterior of the patient's abdomen to warm the fluid within the stomach to the desired T_(M). In another variation, the exogenous substance, e.g. elemental magnesium, itself causes an exothermic reaction to occur in the stomach.

Yet another approach providing a exogenous substance 120 to an intragastric device comprising T_(M)=50° C. modified PCL is the ingestion of 500 mL of alkaline solution (e.g. saturated sodium bicarbonate) pre-warmed to 55° C. Said solution initiates an exothermic reaction upon neutralization with the stomach acid, warming the stomach contents above the 50° C. PCL melting point.

Emptying and Deswelling Degradation

Certain embodiments of the present invention comprise a system for the rapid degradation and volume reduction of an intragastric hydrogel-containing medical device. The system disclosed herein consists of three paired materials: a degradable device structural element, a hydrogel and a tuned dissolution (or deswelling) solution selected to degrade the structural element and deswell the particular hydrogel according to their underlying chemical properties. The system is employed in the following way: First, an intragastric device containing a hydrogel is swallowed, ingested or inserted into a patient's stomach. The hydrogel swells when exposed to fluid and takes up space within the stomach lumen. Following a sufficient residence time determined by the patient or by an administering healthcare professional, a hydrogel deswelling agent is ingested by or administered to the patient. The deswelling agent (which may be in the form of a solid, liquid, or gas) causes the device to release the enclosed hydrogel by degrading a structural element (a stitch, a line of stitches, a seam, a glue, a patch, a plug, or other known structural elements in the art). The deswelling agent then rapidly decreases the volume of the hydrogel to facilitate pyloric passage and safe distal GI tract transit.

Numerous structural elements susceptible to degradation following exposure to particular aqueous conditions are known in the art. Examples include the polymer polycaprolactone which can be extruded into plaques, films, monofilaments, plugs, and other structural elements. Polycaprolactone (available from The DURECT Corporation, Birmingham, Ala.) has a melting temperature of approximately 60° C. and can be thermoformed, molded, or extruded into a number of structural elements known in the art. Modified PCL with melting temperatures ranging from ˜40-60° C. (available from Zeus Industrial Products of Orangeburg, SC) can also be thermoformed, molded, or extruded into a number of structural elements known in the art.

Device structural elements can also be produced from materials that selectively dissolve when exposed to elevated pH conditions, but remain substantially structurally intact when exposed to lower pH conditions. For example, stretch-drawn fibers can be produced from poly(methacrylic acid-co-methyl methacrylate), available as EUDRAGIT S-100, or poly(methyl acrylate-co-methyl methacrylate-co-methacrylic acid) co-polymer, available as EUDRAGIT FS-30D, both from Evonik Industries of Darmstadt, Germany. These polymers can be formulated with Tri Ethyl Citrate (TEC) and extruded into filaments which can be used to close the seams of an intragastric device. For example, a 70% EUDRAGIT S-100 and 30% Tri Ethyl Citrate (available from Samrudhi Pharmachem of Mumbai, India) mix can be blended and extruded into fiber using a single screw extruder. The resulting filament can then be used to sew a seam of an intragastric device filled with hydrogel. The resulting fiber and seam remain substantially structurally stable (for example, having mechanical properties such as strength which do not change over time) but rapidly degrade (for example, by dissolving) at a pH greater than about 7.

Some hydrogels may be deswelled by exposure to an aqueous solution comprising elevated salt concentrations. FIG. 15 illustrates this deswelling effect and shows the degree of swelling for several cross-linked polyacrylic acid and cross-linked polyacrylamide hydrogels after exposure to solutions containing various solutes at various concentrations. Each subject hydrogel was loaded into a permeable polyester mesh pouch and exposed sequentially to the listed environments.

Pouches were created from 9.5 cm×22.0 cm pieces of polyester mesh (available as China Silk from Ryco of Lincoln, RI), folded in half along the long edge, closed along the long edge and one short edge with fabric glue (available as Bish's Tear Mender from True Value Hardware of Cambridge, Mass.), and filled with 1.0 gram of one of the following superabsorbent hydrogels: Waste Lock 770 (available from M2 Polymer Technologies, Inc.), Waste Lock PAM (available from M2 Polymer Technologies, Inc.), Tramfloc 1001A (available from Tramfloc of Tempe, AZ), Water Crystal K (available from WaterCrystals.com), Hydrosource (available from Castle International Resources of Sedona, AZ), poly(acrylamide-co-acrylic acid) potassium salt (available from Sigma-Aldrich), and Soil Moist (available from JRM Chemical of Cleveland, Ohio). The pouches were closed along the remaining short edge with three square knots of a polyester sewing thread, weighed, placed in a beaker filled with 350 mL tap water, and incubated at 37 C for 1 hour. The pouch was weighed after 30 minutes and 1 hour in tap water. The pouch was then submerged in a beaker incubated at 37 C containing 350 mL of 2% sodium chloride, blended dog food (150 grams of Adult Advanced Fitness Dry Dog Food from Hill's Science Diet blended in 50 mL simulated gastric fluid [2 grams sodium chloride, 3.2 grams pepsin, 7 mL hydrochloric acid, brought to 1 liter with tap water], and brought to IL with tap water), pH 3 buffer (available as Hydrion pH 3 buffer from Micro Essential Laboratory of Brooklyn, NY), and 2.5% calcium chloride for 3.5 hours each. In between each of these incubations, the pouches were submerged in a beaker containing 350 mL tap water incubated at 37 C. The pouch was weighed after each incubation. The pouches became lighter after each incubation in the different media but regained most of their mass after incubation in tap water. However, in 2.5% calcium chloride, each pouch lost a significant amount of mass and could not regain this mass after incubation in tap water (data not shown).

The hydrogels shown in FIG. 15A are comprised of either cross-linked polyacrylic acid or cross-linked polyacrylamide, materials that are widely used in medical device applications. As evidenced by this data, administration of a deswelling solution comprised of 2.5% Calcium Chloride could rapidly decrease hydrogel volume by ten times or more. Therefore, any of the hydrogels disclosed in FIG. SGL7 paired with a 2.5% Calcium Chloride deswelling solution constitute a system for ionic strength-based construct degradation.

The hydrogels shown in FIG. 15B are comprised of either cross-linked polyacrylic acid or cross-linked polyacrylamide, materials that are widely used in medical device applications. The composition and fabrication of this hydrogel is reported in the literature (Gemeinhart, et al., 2000). As evidenced from the data, swelling extent of this hydrogel rapidly increases above pH 3. This hydrogel is comprised of highly biocompatible materials and is therefore suitable for ingestion by a patient as part of a space occupation device. The hydrogel will swell in a normal gastric environment. When the device is ready to be eliminated, a low pH deswelling solution could be administered to the patient to rapidly deswell the hydrogel.

FIG. 15C depicts the swelling performance of a chitosan/poly(vinyl alcohol) superporous hydrogel in solutions at different pHs. The composition and fabrication of this hydrogel is reported in the literature (Gupta, et al., 2010). As shown in the FIG. 15C, the swelling extent of this hydrogel rapidly decreases above pH 3. This hydrogel is comprised of highly biocompatible materials and could be swallowed by a patient as part of a space occupation device. This hydrogel is swollen with a solution at low pH (below 3). When the device is ready to be eliminated, an elevated pH deswelling solution (pH>3) is administered to the patient to rapidly de-swell the hydrogel.

Exemplary Embodiment 1

One embodiment of the system for rapid hydrogel construct degradation comprises a hydrogel-containing intragastric device and deswelling agent capable of simultaneously opening the device and deswelling the hydrogel. The construct in this exemplary embodiment is fabricated using the following materials: Pouches are created from 9.5 cm×22.0 cm pieces of polyester mesh (available as China Silk from Ryco of Lincoln, RI), folded in half along the long edge, closed along the long edge and one short edge with fabric glue (available as Bish's Tear Mender from True Value Hardware of Cambridge, Mass.), and filled with 1.0 gram of Waste Lock 770 hydrogel (available from M2 Polymer Technologies, Inc.). The pouch(es) are closed along the remaining short edge with, for example, three square knots of modified Polycaprolactone thread (available from Zeus Industrial Products of Orangeburg, SC) processed to melt at 47° C. The corresponding dissolution solution comprises a 2.5% Calcium Chloride aqueous solution heated to 55° C. This solution degrades the modified polycaprolactone structural element (knots holding the pouches closed) and deswells the salt-sensitive hydrogel.

Variations of the gastric devices described in the devices, systems and methods above are suited for delivery via a natural ingestion process. To facilitate ingestion, such gastric devices, systems and methods can be combined with a shaped body that allows ingestion of the gastric device and reduces a gag reflex or swallowing resistance by the individual.

As discussed and shown previously in FIG. 1A, gastric device assemblies 100 can be provided with an encapsulation to facilitate delivery of the device assembly to a patient's stomach by natural swallowing mechanisms. In embodiments wherein the assemblies' deployment profile volumes are less than about 1.4 milliliters the encapsulation may be a large, thin walled capsule as is well known in the pharmaceutical art and available in many sizes and materials from, for example, Capsugel, 412 Mt. Kemble Ave., Suite 200C, Morristown, N.J. 07960. As shown in the table in FIG. 16, the largest standard hard gelatin capsule for human use is size 000, with a volume of about 1.4 milliliters. Notably, even this size hard gelatin capsule is hard for many patients to swallow.

In many applications, however, the deployment profile of device assembly has a volume on the order of 3 milliliters or larger. In these embodiments, the gastric device assembly may also comprise an ingestible delivery system 400 that is anatomically-adapted and elastically deformable, hereafter also referred to as an anatomically-adapted dosage form, or just the dosage form. Dosage form 400, illustrated notionally in FIG. 17A, comprises an shaped body 403 of biocompatible material, where the volume, shape, and material properties of the body is designed to mimic a large bolus of food as formed by the human mouth just prior to initiating swallowing and where shaped body 403 at least partially encloses device assembly 403. That is, the device embedded in the anatomically-adapted dosage form is designed to be more easily swallowed than other dosage forms because the anatomically-adapted dosage form conforms to what the human body is used to swallowing, thereby reducing rejection of the device by gagging. Note that the figure illustrates two alternative embodiments of shaped body 403. In some embodiments, shaped body 403 comprises a visco-elastic solid 405 while in other embodiments shaped body 403 comprises a plethora of discrete particles 404.

In some embodiments, shaped body 403 is optionally surrounded by an outer layer 401 of biocompatible and degradable material. In some variations outer layer 401 is a film-like layer of biocompatible, degradable material while in other variations the outer layer comprises a thicker layer. In one embodiment outer layer 401 comprises formulations including HPMC (hydroxymethylcellulosic acid) or others known in the art. More generally, the ingestible delivery system may be used to facilitate the ingestion of devices or substances other than the device assemblies shown herein. Hereafter, therefore, the device or substance encapsulated by ingestible delivery system 400 can also be referred to by the more generic term “payload” 402.

Anatomical adaptations of dosage form 400 generally fall into two categories. The first category of anatomical adaptation is shape. In one exemplary embodiment the dosage form is shaped like a bolus of masticated food at the back of the (typical) human throat, more specifically like a bolus of food just as it is being propelled backward in the throat by the tongue. The details of this dosage form shape are discussed below.

The second category of anatomical adaptation is the consistency or mouth-feel of shaped body 403. The inventors have determined that a large dosage form is swallowed more easily when it is deformably compliant to pressure applied to it by the tongue and throat. As with shape, anatomical adaptation for consistency requires making the shaped body feel “natural” to the throat. While there is a wide range of naturally swallowed foods, it is possible to identify those consistencies (in the general sense) that lend themselves to easy swallowing despite being large, such as raw oysters, Jell-O® “shots”, and, as most children learn, large boluses of bubble gum. These boluses are all somewhat visco-elastic with a generally smooth and lubricious surface (at least when in contact with the oral environment). Visco-elasticity, for the purposes of this specification, means that the material deforms under mechanical stress (i.e., pressure), with the material being displaced by the deformation, but largely returns to its initial condition when the stress is removed. The amount of deformation a material can undergo before exceeding its elastic limit (e.g., tearing or being permanently deformed), how much pressure is required to deform a material by a certain amount, in a certain time, and the rate of return to its initial condition are highly variable in different visco-elastic materials.

The shaped body described herein need not be strictly visco-elastic, which implies that the deformation mechanism is displacement. Other materials that deform under pressure and are self-restoring, elastic foams for example, are also suitable for use in the shaped body. Similarly, the shaped body may comprise a plethora of individual pellets, balls, or particles contained within and constrained by the thin layer of biocompatible and degradable material 401. By suitable design and material selection of outer layer 401 and particles 404, this “beanbag” embodiment of shaped body 403 behaves as if it were visco-elastic. For example, an elastic outer layer 401 can provide the restoring force to return the plethora of particles to, or near to, their original positions.

As shown in the notional illustration of FIG. 17A, shaped body 403 cushions the throat from sensing that it is swallowing payload 402. In some variations the payload is generally soft and/or pliable. In such variation shaped body 403 may be approximately 1 or 2 millimeters thick in places, serving primarily to smooth the exterior contour of dosage form 400. In other variations the payload is generally hard and/or rigid. In such a variation shaped body 403 may need to be greater than 2 millimeters thick.

As shown in notional illustration FIG. 17B in some variations payload 402 is surrounded by a containment layer 407, wherein, generally, containment layer 407 forms a “container” to keep payload 401 from spreading out or expanding during the manufacturing process or pre-deployment storage. For example, some payloads comprise large objects that are folded and/or compressed to make them suitably sized for swallowing; often these folded payloads are irregularly shaped. Containment layer 407 holds these objects in their compressed or folded state while being encased by outer body 403 during manufacture. Further, in some variations, containment layer 407 smoothes the contours of folded payloads to prevent their irregularities from being sensed by the mouth and throat. In some embodiments containment layer 407 may be molded or formed around payload 402 while the payload is held in its compressed state by external means. With the external means removed, the then contained payload can be encased in the outer body. In many embodiments containment layer 407 may be formed from the same material as outer body 403.

As shown in the notional illustration of FIG. 17C in some variations dosage form 400 comprises a “softgel” layer 409. In this variation the exterior softgel layer 409 is fabricated to the inventive shape described herein and is used to surround and contain a liquid or gel-like filling material 412 and the payload. In some variations liquid or gel-like filling material 412 is the payload. For example, the payload may be a large volume (greater than, say, 3 milliliters) of unpleasant tasting liquid, e.g., a fish oil dietary supplement.

In some variations the shaped body comprises a material that dissolves, degrades, becomes structurally unstable, etc. in the gastric environment or in an aqueous environment. Preferably a dissolvable shaped body dissolves in 1 to 20 minutes after exposure to those environments. More preferably a dissolvable shaped body dissolves in 1 to 10 minutes, and most preferably a dissolvable shaped body dissolves in 1 to 5 minutes. In some variations, wherein shaped body 403 comprises a plethora of particles 404 contained within outer layer 401, outer layer 401 comprises a material that dissolves in the gastric environment or in an aqueous environment. Preferably a dissolvable outer layer dissolves in 1 to 20 minutes after exposure to those environments. More preferably a dissolvable outer layer dissolves in 1 to 10 minutes, and most preferably a dissolvable outer layer dissolves in 1 to 5 minutes. In other variations the shaped body is coated or covered with a generally thin protective material (not illustrated) to inhibit too rapid dissolution of the shaped body material or the outer layer material, where too rapid dissolution means dissolution during the passage of the ingestible delivery system 400 from the mouth to the intended location in the gastric system, usually the stomach, for example, in the esophagus. Generally the thin protective material does not have the same structural properties as outer layer 401; it only serves to protect the system from premature payload release.

In other variations, where the payload is either self expanding or can be expanded via an external trigger or process, shaped body 403 is, by design, structurally weak enough to release the payload from the internal pressure of the expanding payload. In some embodiments the material of shaped body 403 (or outer layer 401) is inherently weak enough to allow the expanding payload to break out while in other embodiments the shaped body or outer layer must be intentionally weakened, for example, by scored lines or perforations. In other variations the shaped body degrades upon exposure to the gastric environment to the required structural weakness. Preferably, structural weakness is achieved within 1 to 20 minutes after exposure to those environments. More preferably structural weakness is achieved within 1 to 10 minutes, and most preferably structural weakness is achieved within 1 to 5 minutes. The required structural weakness may be achieved by combinations of design features, for example the combination of shaped body scoring and shaped body material gastric degradation.

Shaped Body Configurations

In one variation dosage form 400 has an anatomically adapted shape. The inventors have determined that oral dosage forms with volumes greater than approximately 1 milliliter are more easily swallowed by many humans when the shape of the dosage form mimics a bolus of food at the back of the throat, e.g., between the soft palate and the pharynx. FIG. 18 is an illustration of a cut-away view of the human swallowing anatomy. In the figure a food bolus is depicted at the moment of swallowing. Immediately preceding this moment the food was masticated in the mouth and pushed rearwardly to its present location by the tongue, which is continuing to push the bolus rearwardly and upwardly against the hard palate. The pushing action of the tongue at this stage of swallowing shapes the bolus to conform generally to the hard palate. The inventors have determined that the shape thereby obtained an anatomically preferred shape for food bolus passage past the uvula, not illustrated, and into and through the pharynx. Dosage form 400 has been designed to generally conform to this anatomically preferred shape.

FIG. 19 presents a perspective view of one embodiment of dosage form 400, wherein the point of view is slightly above and to the side of dosage form 400. The vector triplet in corner of the image is provided to orientation in this and subsequent figures, where Z is the lingual axis with the positive Z-direction being from a labial end 430 to a pharyngeal end 440, Y is the lingual to palate direction, with the positive Y-direction pointing from the tongue to the roof of the mouth, and X is the cross-lingual or buccal-to-buccal axis, with the positive X-direction pointing from the left cheek to the right cheek. Dosage form 400 comprises a top, or palatal, surface 410 and a bottom, or lingual, surface 420, where the palatal and lingual surfaces are conventionally understood to be the surfaces above and below respectively an “equatorial” division.

FIG. 20 is a top view (i.e., looking into the X-Z plane) of the embodiment of FIG. 19 that illustrates a “pumpkin seed” profile of dosage form 400 in this plane; specifically, the illustration shows an asymmetry of the rate of taper between pharyngeal end 440 and labial end 430, the tapering in each direction starting at the point of greatest cross-lingual width, annotated as Wx. In one embodiment the width Wx is disposed approximately 60% of the distance between a labial end 430 and a pharyngeal end 440.

FIG. 21 is a side view of the embodiment of FIG. 19 (i.e., looking into the Y-Z plane) which clearly illustrates a pharyngeal-end thickness taper and a labial-end thickness bulge 415 of dosage form 400, in this embodiment. In one embodiment the Y-thickness at its maximum is approximately 13 millimeters and tapers down to approximately 4 millimeters as it approaches the pharyngeal tip. In some embodiments labial end 430 is smoothly truncated to form a lingual reaction surface 435. Lingual reaction surface 435 provides a flatter region against which the tongue can push as it urges the dosage form through the pharynx.

Surprisingly, it will be noted that in this embodiment dosage form 400 is thickness-tapered towards its pharyngeal end 440. This tapering is different from the more conventional depiction of a food bolus, as illustrated in FIG. 18, in which the bolus more tapered in thickness toward its labial end. The inventors have determined that the tongue pushes the food bolus down the back of the throat against the resistance of the pharynx more than it pushes the bolus upward against the hard palate; hence the bolus is being squeezed through a restriction and “piles up” against the tongue pushing at its lingual end.

FIG. 22A is an end view of the embodiment of FIG. 19 (i.e., looking into the X-Y plane) which illustrates that top surface 410 of dosage form 400 substantially conforms to the shape of the palatal arch. In some variations bottom surface 420 comprises a lingual trough 422, disposed parallel to the Z-axis. In one embodiment the lingual trough is approximately 3 millimeters deep and runs from the labial end toward the pharyngeal end for essentially the entire of the length of dosage form 100. In other variations, as illustrated in the end view in FIG. 22B, bottom surface 420 comprises a shallow, elliptically convex surface.

The overall volume of the oral dosage form is designed to accommodate the volume of the payload by adjusting the dimensions of the dosage form along all three dimensions while simultaneously maintaining the anatomical adaption that fits dosage form to the human palatal arch. Thus, in some embodiments Wx may be between 8 and 35 millimeters, the overall Z-axis length may be between 10 and 65 millimeters, and the Y-axis thickness, at the “tallest” point, may be between 4 and 15 millimeters. In one embodiment the volume of the dosage form is approximately 6 milliliters.

It will be noted that the requirements for the shape and consistency of a ingestible delivery system span a continuum based on the desired volume and the inherent flexibility or lack thereof of the gastric implant. For example, for very small implant volumes, shaped body shape and consistency are less important for swallowing while for very large and/or more inflexible implant volumes a carefully crafted shaped body shape is required for successful swallowing and the consistency must be compatible with the mouth and throat's expectations.

The qualitative, notional graph of FIG. 23 illustrates this relationship. The graph comprises two axes. The horizontal axis is the shape factor axis, where 0 indicates that the shape of the dosage form is arbitrary (nominally a sphere) whereas a shape factor of 100 indicates that the dosage form is “perfectly” anatomically adapted in accordance with this invention. The vertical axis is the visco-elasticity factor axis, where again 0 indicates that the consistency of the shaped body is arbitrary and nominally presents a hard, solid exterior. A VE factor of 100 again indicates that the dosage form is “perfectly” anatomically adapted, for example feeling like a raw oyster to the throat.

The graph further comprises a series of contour lines delineating the preferred balance of shape and VE factors for various dosage form volumes. For example, dosage forms with volumes greater than V_(MAX) are preferably designed to operate in the upper right corner of the graph, that is, with a shape very close to ideal and a consistency very much like an oyster. On the other hand dosage forms with relatively smaller volumes, say less than V₂, can be designed with a range of shape and consistency. On this notional graph, a dosage form with volume V₂ can have a shape factor between about 25 and 100 if it has the “oyster” consistency or it can be anywhere between the oyster and relatively hard and non-compliant if it has a shape nearing 100.

Shaped Body Materials

In order to cushion the potentially rough, stiff, or hard texture of the payload and to create a deformable and flexible final structure, shaped body 403, in some embodiments, comprises a visco-elastic, gel-like material. In other embodiments a similar material is enclosed in the region between the outer surface of payload 402 and the inner surface of outer layer 401. In some variations outer layer 401 functions to constrain the material of shaped body 403 to keep it surrounding payload 402. In other variations outer layer 401 protects the shaped body material during the period between dosage form manufacture and deployment in the stomach. For example, some gel-like materials may dehydrate during storage if not protected by a substantially water-vapor impermeable thin film.

Example biocompatible gels known in the art include compositions of cross-linked polyacrylic and polymethacrylic acids as well as blends of hydrophilic cellulose derivatives and polyethylene glycol (PEG). Other examples of gels known in the art that may be utilized in this application include but are not limited to cellulose-derivatives, hyaluronic acid and derivatives, pectin and traganth, starches, sulfated polysaccharides, carrageenan, alginates and gelatin. Hydrophobic gels such as silicone gels are known in the art and may be employed.

In one exemplary embodiment shaped body 403 may be made from gelatin. In an exemplary embodiment a suitable consistency can be achieve by combining 1 3-oz. box of Jell-O® gelatin dessert and 0.5 oz. of KnoX® Brand Original Gelatine [sic] with enough hot water (˜boiling) to make about 1.5 cups of mixture. In other embodiments other materials and/or other concentrations of gelatin also form shaped bodies with suitable consistencies.

In other embodiments other materials and/or other concentrations of gelatin also form shaped bodies with suitable consistencies. In one exemplary embodiment shaped body 403 may be made from a 1% solution of agar agar in water with or without 1% thickening agent. Thickening agents include locust bean gum and guar gum. In yet another exemplary embodiment shaped body 403 may be made from a solution of 2.5% pectin with or without poly(vinyl alcohol) or plasticizer. Examples of plasticizer include glycerol and glycerin.

In other embodiments other materials also form shaped bodies that comprise an outer layer. In one exemplary embodiment shaped body 6203 may be made from 2% hydroxypropylmethylcellulose (HPMC). In yet another exemplary embodiment, shaped body 403 may be made by wrapping a thin sheet of water soluble poly(vinyl alcohol) around the payload. In preferred embodiments the outermost surface of dosage form 400 is smooth and either inherently lubricious or can be made lubricious by coating or wetting with an appropriate lubricant, typically water.

In some variations it is desirable to store an ingestible delivery system to prevent desiccation. For example, the prepared payload may be sealed in water vapor tight plastic. In another example, the prepared payload may be stored with an edible oil coating.

The devices and systems described below are provided as examples of details of construction and arrangement of components. The invention includes variations of devices, systems and methods that capable of other embodiments and of being practiced or of being carried out in various ways. Also, the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting. The use of “including,” “comprising,” “having,” “containing,” “involving,” and variations thereof herein is meant to encompass the items listed thereafter and equivalents thereof as well as additional items. 

1. An ingestible delivery system comprising: a shaped body having an anatomically adapted shape, the anatomically adapted shape including an axial length being greater than a width, and where the width is greater than a thickness of the anatomically adapted shape, and wherein a first and second end of the oral dosage shape are smooth and elliptically convex; the shaped body comprising a visco-elastic material being deformably compliant in response to external pressure and having a lubricious surface, where the shaped body reduces a gagging reflex allowing for ingestion of the shaped body; and a gastric device at least partially encapsulated within the shaped body in a reduced profile, the gastric device being releaseable from the shaped body subsequent to ingestion such that the gastric device can assume an expanded profile.
 2. The ingestible delivery system of claim 1, where the anatomically adapted shaped body further comprising: a lingual axis length extending between a labial end and a pharyngeal end; a buccal-to-buccal axis width; a lingual-palate axis thickness extending between a lingual surface and a palatal surface; and where the lingual axis length is greater than the buccal-to-buccal axis width which is greater than the lingual-palate thickness and wherein cross-sections of the palatal surface are substantially convex, smoothly varying curves approximating the human palatal arch in both the lingual and buccal axes and the lingual surface is optionally shallowly elliptically convex and wherein the lingual surface and the palatal surface have been adapted to conform generally to the corresponding anatomical features.
 3. The ingestible delivery system of claim 2, wherein the lingual-palate thickness is downwardly tapered toward the pharyngeal end of the shaped body.
 4. The ingestible delivery system of claim 2, wherein the labial end is bulbous.
 5. The ingestible delivery system of claim 2, further comprising a lingual reaction surface disposed at the labial end of the shaped body.
 6. The ingestible delivery system of claim 2, further comprising a concave lingual trough disposed on the lingual surface and parallel to the lingual axis.
 7. The ingestible delivery system of claim 2 wherein that palatal surface comprises two laterally symmetric surfaces said surfaces generally adapted to match the roof of the mouth in the general vicinity of the junction between the hard and soft palate.
 8. The ingestible delivery system of claim 2 further comprising a smooth surface texture.
 9. The ingestible delivery system of claim 1, where the shaped body is degradable in a normal human digestive tract.
 10. The ingestible delivery system of claim 1, having a surface comprising material having a coefficient of friction that decreases when lubricated.
 11. The ingestible delivery system of claim 1, where the gastric device comprises a liquid impermeable surface material forming a device body having an interior reservoir, the device body having a deployment profile and expandable to an active profile upon receiving the liquid filler material within the interior reservoir; a liquid tunnel having at least one wall and defining an elongated passage, at least a portion of the liquid tunnel extending within the interior reservoir, and where the at least one wall of the liquid tunnel is pre-disposed to obstruct the elongated passage to prevent fluid flow therethrough; a fluid conduit having a distal portion located within the elongated passage of the liquid tunnel to create a fluid path through the elongated passage for delivery of the fluid into the interior reservoir, and where the fluid conduit is removable from the liquid tunnel, such that upon removal of the fluid conduit, the at least one wall of the liquid tunnel obstructs the elongated passage to prevent fluid therethrough the elongated passage; and a release channel formed by an elongated section of liquid impermeable material, where the elongated section of liquid impermeable material is inverted into the interior reservoir and temporarily restrained therein, wherein, when temporarily restrained, the release channel is closed to prevent liquid transfer to or from the patient's body.
 12. The ingestible delivery system of claim 11, where the elongated section of liquid impermeable material forming the release channel comprises a portion of the surface material.
 13. The ingestible delivery system of claim 1, further comprising a release material that temporarily restrains the elongated section of material.
 14. The ingestible delivery system of claim 13, where the release material comprises a temperature sensitive material that degrades upon reaching a pre-determined temperature.
 15. The ingestible delivery system of claim 13, where the release material comprises a rate of hydrolysis that causes degradation of the release material after at least 2 weeks.
 16. The ingestible delivery system of claim 13, where on the addition of the liquid filler material to the interior reservoir, the release material begins to structurally degrade to release the elongated section of material from restraint.
 17. The ingestible delivery system of claim 13, where the release material is mechanically fastened to the elongated section of material.
 18. The ingestible delivery system of claim 1, where the gastric device comprises a device body having an interior reservoir, the device body having a deployment profile and being expandable to an active profile upon addition of the liquid filler material into the interior reservoir; an elongate flexible valve having at least one wall and extending within the interior reservoir, the at least one wall of the elongate flexible valve being pre-disposed to obstruct fluid flow through the elongate flexible valve; a fluid conduit having a distal portion removably located within the elongate flexible valve to create a fluid path between an exterior of the device body and the interior reservoir for delivery of the fluid into the interior reservoir and where removal of the fluid conduit from the elongate flexible valve permits the at least one wall to close to obstruct fluid flow through the elongate flexible valve; and a second fluid passage formed by a second section of material being liquid impermeable, where the second section of material is inverted and temporarily restrained within the reservoir, and where freeing the second section of material from restraint permits opening of the second fluid passage to allow egression of fluids from the interior reservoir.
 19. The ingestible delivery system of claim 1, where the gastric device comprises a device assembly comprising a skin, a fluid transfer member, and a release material, the skin forming a perimeter of the device assembly defining a reservoir therein, where the release material is coupled to at least a portion of the skin forming an invaginated section having a passage extending to an opening such that the invaginated section and release material are coupled to create a physical barrier preventing fluid from passing through the passage of the invaginated section, where the skin is liquid impermeable and where the fluid transfer member permits delivery of fluids into the reservoir through the physical barrier; the device assembly having a deployment profile and an active profile, where the deployment profile is smaller than the active profile and permits deployment of the device assembly within a gastric the space in the patient's body; where the fluid transfer member comprises a sealable fluid path and a removable conduit located therein and having a proximal end and a device end, where a length of the conduit permits delivery of fluid into the reservoir when the device assembly is located within the patient's body and the proximal end is positioned outside of the patient's body, where the conduit permits delivery of the liquid filler material into the reservoir to cause the device assembly to expand from the deployment profile to the active profile such that the device assembly occupies at least a portion of the gastric space within the patient's body; and wherein removal of the conduit allows the sealable fluid path to seal and prevents the liquid filler from escaping therethrough, and wherein breakdown of the release material opens the passage to allow the liquid filler material to pass through the invaginated section resulting in reduction of a size of the device assembly from the active profile.
 20. The ingestible delivery system of claim 1 being at least partially elastically deformable in response to lingual and pharyngeal pressure. 